# How can I use modulo to do REVERSE (backwards) wrap-around (overflow)?

Can the expression ((x-1) % k + k) % k be simplified futher?

This is slightly more of a math question than is is a programming question, but it shows up very frequently in coding. Suppose we iterate over a calendar's months. This can be shown with numbers as:

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

where both integers will be between 0 and 11 (inclusive). Thus, for any whole number 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.

What if we want to do it backwards?

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

Is the code above the only way to do it, or is there any ingenious and elegant way to simplify the expression ((x-1) % k + k) % k?

Now changing the range of the months to [1,12] will simplify stuff, but when dealing with matrices, arrays, etc. where index numbers begin at 0, we can't change the range...

-

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. –  Mankarse Feb 9 at 6:10
-1 % 12 = 11 -- is it so in c++? –  Anton Kovalenko Feb 9 at 6:10
@Mankarse22 does it? I just tried it in my calculator, haven't gotten a chance to try it in a compiler. –  Night5h4d3 Feb 9 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). –  Mankarse Feb 9 at 6:18
@Mankarse Thank you for pointing that out, I think I've corrected the math in my answer. –  Night5h4d3 Feb 9 at 6:21

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);
}
-