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One of my pet hates of C-derived languages (as a mathematician) is that

(-1) % 8 // comes out as -1, and not 7

fmodf(-1,8) // fails similarly

What's the best solution?

C++ allows the possibility of templates and operator overloading, but both of these are murky waters for me. examples gratefully received.

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Add the output back to N ;D? –  sova Oct 23 '10 at 9:20
I don't think this is quite a "duplicate" of stackoverflow.com/questions/828092/… under the official definition. It's not true that this question's answers can be merged into that one's, because this question only asks about modulus, not also division. But I think this question is covered by that one, so it's close. My answer is there already, FWIW. –  Steve Jessop Oct 23 '10 at 11:25
Maybe that thread should be split, as it asks two separate questions. the best way to do that might be to re-ask the division question separately and then point it towards that answer. I will leave it to someone who understands the mechanisms of this website better. –  P i Oct 23 '10 at 15:45
@Pi owhere is % said to be the modulo... it's the remainder. –  oldrinb Sep 9 '12 at 8:29

11 Answers 11

up vote 40 down vote accepted

First of all I'd like to note that you cannot even rely on the fact that (-1) % 8 == -1. the only thing you can rely on is that (x / y) * y + ( x % y) == x. However whether or not the remainder is negative is implementation-defined.

Now why use templates here? An overload for ints and longs would do.

int mod (int a, int b)
   int ret = a % b;
   if(ret < 0)
   return ret;

and now you can call it like mod(-1,8) and it will appear to be 7.

Edit: I found a bug in my code. It won't work if b is negative. So I think this is better:

int mod (int a, int b)
   if(b < 0) //you can check for b == 0 separately and do what you want
     return mod(-a, -b);   
   int ret = a % b;
   if(ret < 0)
   return ret;

Reference: C++03 paragraph 5.6 clause 4:

The binary / operator yields the quotient, and the binary % operator yields the remainder from the division of the first expression by the second. If the second operand of / or % is zero the behavior is undefined; otherwise (a/b)*b + a%b is equal to a. If both operands are nonnegative then the remainder is nonnegative; if not, the sign of the remainder is implementation-defined.

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I just tested the first chunk and that works, though I can't get my head around why! I would hesitate to use it, as I'm not sure whether it would work for any compiler implementation of % that satisfies the criterion of (x / y) * y + ( x % y) == x. where did you get that from, out of curiosity? Is that in the C standard? If it is robust, it may be preferable over my method (below) for integers in terms of speed. –  P i Oct 23 '10 at 10:20
@Ohmu: Yes, that's in the C++ standard. <quote> For integral operands the / operator yields the algebraic quotient with any fractional part discarded; if the quotient a/b is representable in the type of the result, (a/b)*b + a%b is equal to a.</quote> –  Ben Voigt Oct 23 '10 at 19:08
-1. It's been 11 years since this was implementation defined. ISO 9899:1999 defined it, and unfortunately chose the bad definition. –  R.. Oct 23 '10 at 19:53
@Armen: You conveniently deleted the footnote <quote>... integer division follows the rules defined in the ISO Fortran standard, ISO/IEC 1539:1991, in which the quotient is always rounded toward zero</quote>. The new C++ standard upgrades this behavior from "preferred" to mandatory, just like Fortran and C. –  Ben Voigt Oct 23 '10 at 22:03
@Armen: The old spec is broken, but the brokenness is different from the sign issue, and it's easy to miss until you look at the new wording. C++03 didn't have "if the quotient a/b is representable in the type of the result", which causes problems for INT_MIN / -1 (on two's complement implementations). Under the old spec, -32768 % -1 might have to evaluate to -65536 (which also isn't in range of the 16-bit type, yuck!) in order for the identity to hold. –  Ben Voigt Oct 23 '10 at 23:26

For integers this is simple. Just do

(((x < 0) ? ((x % N) + N) : x) % N)

where I am supposing that N is positive and representable in the type of x. Your favorite compiler should be able to optimize this out, such that it ends up in just one mod operation in assembler.

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Doesn't work: for int x=-9001; unsigned int N=2000; it gives 2295, not 999. –  Hubert Kario Jan 29 '12 at 1:33
@HubertKario Maybe check again? There is no way that something modulo 2000 gives 2295, you must have made a mistake. –  Sam Hocevar Nov 28 '12 at 15:41

Here is a C function that handles positive OR negative integer OR fractional values for BOTH OPERANDS

#include <math.h>
float mod(float a, float N) {return a - N*floor(a/N);} //return in range [0, N)

This is surely the most elegant solution from a mathematical standpoint. However, i'm not sure if it is robust in handling integers. Sometimes floating point errors creep in when converting int -> fp -> int.

I am using this code for non-int s, and a separate function for int.

NOTE: need to trap N = 0!

Tester code:

#include <math.h>

float mod(float a, float N)
    float ret = a - N * floor (a / N);

    printf("%f.1 mod %f.1 = %f.1 \n", a, N, ret);

    return ret;

int main (char* argc, char** argv)
    printf ("fmodf(-10.2, 2.0) = %f.1  == FAIL! \n\n", x);

    float x;
    x = mod(10.2f, 2.0f);
    x = mod(10.2f, -2.0f);
    x = mod(-10.2f, 2.0f);
    x = mod(-10.2f, -2.0f);

    return 0;

(Note: You can compile and run it straight out of CodePad: http://codepad.org/UOgEqAMA)


fmodf(-10.2, 2.0) = -0.20 == FAIL!

10.2 mod 2.0 = 0.2
10.2 mod -2.0 = -1.8
-10.2 mod 2.0 = 1.8
-10.2 mod -2.0 = -0.2

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PS: Wouldn't it be awesome if SO could compile & run code like CodePad! –  P i Oct 23 '10 at 9:18
+1 You could add it to metaSO. This would be an awesome feature to have. –  Samrat Patil Oct 23 '10 at 9:23

Best solution for mathematician is to use Python.

C++ operator overloading has little to do with it. You can't overload operators for built-in types. What you want is simply a function. Of course you can use C++ templating to implement that function for all relevant types with just 1 piece of code.

The standard C library provides fmod, if I recall the name correctly, for floating point types.

For integers you can define a C++ function template as (off the cuff) ...

#include <stdlib.h>  // abs

template< class IntType >
IntType mod( IntType a, IntType b )
    IntType const r = a%b;
    return (r < 0? r + abs( b ) : r);

... and just write mod(a, b) instead of a%b.

Disclaimer: untested code.

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your code seems to have the same bug as mine had before my edit. What if b is negative? :) –  Armen Tsirunyan Oct 23 '10 at 9:57
@Armen: thanks! but I'm too lazy to edit for just that... :-) –  Cheers and hth. - Alf Oct 23 '10 at 10:36
Python's modulo operator (%) already does it the way the questioner wants... –  liquidblueocean Jan 30 at 23:53
@ArmenTsirunyan: the r result has to make a = r + b*(a/b) true. no matter how the integer division is implemented the b*something is a multiple of b. this makes r a valid modulo result even if negative. you can add abs(b) to it and it will still be a valid modulo result. –  Cheers and hth. - Alf Jun 26 at 12:42
/* Warning: macro mod evaluates its arguments' side effects multiple times. */
#define mod(r,m) (((r) % (m)) + ((r)<0)?(m):0)

... or just get used to getting any representative for the equivalence class.

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"Get used to getting any representative for the equivalence class"?! That's nonsense. If you wanted that you could just use the original "representative" r. The % operator has nothing to do with equivalence classes. It's the remainder operator and the remainder is well defined algebraically to be nonnegative and less than the divisor. Sadly C defined it the wrong way. Still, +1 for having one of the best answers. –  R.. Oct 23 '10 at 19:58

Oh, I hate % design for this too....

You may convert dividend to unsigned in a way like:

unsigned int offset = (-INT_MIN) - (-INT_MIN)%divider

result = (offset + dividend) % divider

where offset is closest to (-INT_MIN) multiple of module, so adding and subtracting it will not change modulo. Note that it have unsigned type and result will be integer. Unfortunately it cannot correctly convert values INT_MIN...(-offset-1) as they cause arifmetic overflow. But this method have advandage of only single additional arithmetic per operation (and no conditionals) when working with constant divider, so it is usable in DSP-like applications.

There's special case, where divider is 2N (integer power of two), for which modulo can be calculated using simple arithmetic and bitwise logic as


for example

x mod 2 = x & 1
x mod 4 = x & 3
x mod 8 = x & 7
x mod 16 = x & 15

More common and less tricky way is to get modulo using this function (works only with positive divider):

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

This just correct result if it is negative.

Also you may trick:

(p%q + q)%q

It is very short but use two %-s which are commonly slow.

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I have just noticed that Bjarne Stroustrup labels % as the remainder operator, not the modulo operator.

I would bet that this is its formal name in the ANSI C & C++ specifications, and that abuse of terminology has crept in. Does anyone know this for a fact?

But if this is the case then C's fmodf() function (and probably others) are very misleading. they should be labelled fremf(), etc

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I believe another solution to this problem would be use to variables of type long instead of int.

I was just working on some code where the % operator was returning a negative value which caused some issues (for generating uniform random variables on [0,1] you don't really want negative numbers :) ), but after switching the variables to type long, everything was running smoothly and the results matched the ones I was getting when running the same code in python (important for me as I wanted to be able to generate the same "random" numbers across several platforms.

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define  MOD(a, b)       ((((a)%(b))+(b))%(b))
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unsigned mod(int a, unsigned b) {
    return (a >= 0 ? a % b : b - (-a) % b);
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I would do:

((-1)+8) % 8 

This adds the latter number to the first before doing the modulo giving 7 as desired. This should work for any number down to -8. For -9 add 2*8.

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