# Is there an expression using modulo to do backwards wrap-around ("reverse overflow")?

For any whole number input W restricted by the range R = [x,y], the "overflow," for lack of a better term, of W over R is W % (y-x+1) + x. This causes it wrap back around if W exceeds y.

As an example of this principle, suppose we iterate over a calendar's months:

int this_month = 5;
int next_month = (this_month + 1) % 12;


where both integers will be between 0 and 11, inclusive. Thus, the expression above "clamps" the integer to the range R = [0,11]. This approach of using an expression is simple, elegant, and advantageous as it omits branching.

Now, what if we want to do the same thing, but backwards? The following expression works:

int last_month = ((this_month - 1) % 12 + 12) % 12;


but it's abstruse. How can it be beautified?

tl;dr - Can the expression ((x-1) % k + k) % k be simplified further?

Note: C++ tag specified because other languages handle negative operands for the modulo operator differently.

Your expression should be ((x-1) + k) % k. This will properly wrap x=0 around to 11. In general, if you want to step back more than 1, you need to make sure that you add enough so that the first operand of the modulo operation is >= 0.

Here is an implementation in C++:

int wrapAround(int v, int delta, int minval, int maxval)
{
const int mod = maxval + 1 - minval;
if (delta >= 0) {return  (v + delta                - minval) % mod + minval;}
else            {return ((v + delta) - delta * mod - minval) % mod + minval;}
}


This also allows to use months labeled from 0 to 11 or from 1 to 12, setting min_val and max_val accordingly.

Since this answer is so highly appreciated, here is an improved version without branching, which also handles the case where the initial value v is smaller than minval. I keep the other example because it is easier to understand:

int wrapAround(int v, int delta, int minval, int maxval)
{
const int mod = maxval + 1 - minval;
v += delta - minval;
v += (1 - v / mod) * mod;
return v % mod + minval;
}


The only issue remaining is if minval is larger than maxval. Feel free to add an assertion if you need it.

• ((x-1) + k) % k is the solution! Commented Mar 10, 2017 at 17:47
• The number -1 can't be lower then -(k-1) Commented Aug 19, 2017 at 20:30
• What if your range is 1-12? Commented Sep 10, 2020 at 2:57
• Can anyone explain to me why you divide by mod and then multiply by mod in (1-v/mod)*mod, mathematically this should be pointless but removing it changes the output. Commented Mar 4, 2021 at 3:45
• @BaconMan97 v/mod is an integer division! Commented Mar 5, 2021 at 5:35

k % k will always be 0. I'm not 100% sure what you're trying to do but it seems you want the last month to be clamped between 0 and 11 inclusive.

(this_month + 11) % 12


Should suffice.

• Actually, -1 % 12 == -1. Commented Feb 9, 2013 at 6:10
• -1 % 12 = 11 -- is it so in c++? Commented Feb 9, 2013 at 6:10
• @Mankarse22 does it? I just tried it in my calculator, haven't gotten a chance to try it in a compiler. Commented Feb 9, 2013 at 6:12
• @Night5h4d3: In C++03 the sign is unspecified if either of the operands is negative. In C++11, the sign of the result is the same as the sign of the first operand (see my answer here). Commented Feb 9, 2013 at 6:18
• Yes, this works if your increment/decrement is known or guaranteed to be small. However, (this_month + x + 12)%12 will only work as expected if x >= -12. Below this threshold, you still have the same old problem. Commented Jul 26, 2016 at 15:21

The general solution is to write a function that computes the value that you want:

//Returns floor(a/n) (with the division done exactly).
//Let ÷ be mathematical division, and / be C++ division.
//We know
//    a÷b = a/b + f (f is the remainder, not all
//                   divisions have exact Integral results)
//and
//    (a/b)*b + a%b == a (from the standard).
//Together, these imply (through algebraic manipulation):
//    sign(f) == sign(a%b)*sign(b)
//We want the remainder (f) to always be >=0 (by definition of flooredDivision),
//so when sign(f) < 0, we subtract 1 from a/n to make f > 0.
template<typename Integral>
Integral flooredDivision(Integral a, Integral n) {
Integral q(a/n);
if ((a%n < 0 && n > 0) || (a%n > 0 && n < 0)) --q;
return q;
}

//flooredModulo: Modulo function for use in the construction
//looping topologies. The result will always be between 0 and the
//denominator, and will loop in a natural fashion (rather than swapping
//the looping direction over the zero point (as in C++11),
//or being unspecified (as in earlier C++)).
//Returns x such that:
//
//Real a = Real(numerator)
//Real n = Real(denominator)
//Real r = a - n*floor(n/d)
//x = Integral(r)
template<typename Integral>
Integral flooredModulo(Integral a, Integral n) {
return a - n * flooredDivision(a, n);
}


Easy Peasy, do not use the first module operator, it is superfluous:

 int last_month = (this_month - 1 + 12) % 12;


which is the general case

In this instance you can write 11, but I would still do the -1 + 12 as it more clearly states what you want to achieve.

Note that normal mod causes the pattern 0...11 to repeat at 12...23, 24...35, etc. but doesn't wrap on -11...-1. In other words, it has two sets of behaviors. One from -infinity...-1, and a different set of behavior from 0...infinity.

The expression ((x-1) % k + k) % k fixes -11...-1 but has the same problem as normal mod with -23...-12. I.e. while it fixes 12 additional numbers, it doesn't wrap around infinitely. It still has one set of behavior from -infinity...-12, and a different behavior from -11...+infinity.

This means that if you're using the function for offsets, it could lead to buggy code.

If you want a truly wrap around mod, it should handle the entire range, -infinity...infinity in exactly the same way.

There is probably a better way to implement this, but here is an easy to understand implementation:

// n must be greater than 0
func wrapAroundMod(a: Int, n: Int) -> Int {
var offsetTimes: Int = 0

if a < 0 {
offsetTimes = (-a / n) + 1
}

return (a + n * offsetTimes) % n
}

• This should be the correct answer! Can you give to us a improved version without branching? Commented Apr 8, 2021 at 14:54

Not sure if you were having the same problem as me, but my problem was essentially that I wanted to constrain all numbers to a certain range. Say that range was 0-6, so using %7 means that any number higher than 6 will wrap back around to 0 or above. The actual problem is that numbers less than zero didn't wrap back around to 6. I have a solution to that (where X is the upper limit of your number range and 0 is the minimum):

if(inputNumber <0)//If this is a negative number
{
(X-(inputNumber*-1))%X;
}
else
{
inputNumber%X;
}

• Here is a simplified version to get values between 0 and maxVal (positive modulo) (inputNumber % maxVal + maxVal) % maxVal Commented Jul 7, 2022 at 17:17