According to Google Calculator (13) % 64
is 51
.
According to JavaScript, it is 13
.
console.log(13 % 64);
How do I fix this?
According to Google Calculator (13) % 64
is 51
.
According to JavaScript, it is 13
.
console.log(13 % 64);
How do I fix this?
Number.prototype.mod = function (n) {
"use strict";
return ((this % n) + n) % n;
};
Taken from this article: The JavaScript Modulo Bug
x < n
 e.g. (7 + 5) % 5 === 2
but ((7 % 5) + 5) % 5 == 3
.
Using Number.prototype
is SLOW, because each time you use the prototype method your number is wrapped in an Object
. Instead of this:
Number.prototype.mod = function(n) {
return ((this % n) + n) % n;
}
Use:
function mod(n, m) {
return ((n % m) + m) % m;
}
See: https://jsperf.app/negativemodulo/2
~97% faster than using prototype. If performance is of importance to you of course..
n
s and m
s around the wrong way in your second example @StuR . It should be return ((n % m) + m) % m;
.
The %
operator in JavaScript is the remainder operator, not the modulo operator (the main difference being in how negative numbers are treated):
1 % 8 // 1, not 7
remainder
, it must be larger than 0 by definition. Can't you remember the division theorem from high school?! So maybe you can have a look here: en.wikipedia.org/wiki/Euclidean_division
A "mod" function to return a positive result.
var mod = function (n, m) {
var remain = n % m;
return Math.floor(remain >= 0 ? remain : remain + m);
};
mod(5,22) // 5
mod(25,22) // 3
mod(1,22) // 21
mod(2,22) // 20
mod(0,22) // 0
mod(1,22) // 21
mod(21,22) // 1
And of course
mod(13,64) // 51
#secapplyingthemodoperator
right there in the url :) Anyway, thanks for the note, I took the fluff out of my answer, it's not really important anyway.
The accepted answer makes me a little nervous because it reuses the % operator. What if Javascript changes the behavior in the future?
Here is a workaround that does not reuse %:
function mod(a, n) {
return a  (n * Math.floor(a/n));
}
mod(1,64); // 1
mod(63,64); // 63
mod(64,64); // 0
mod(65,64); // 1
mod(0,64); // 0
mod(1,64); // 63
mod(13,64); // 51
mod(63,64); // 1
mod(64,64); // 0
mod(65,64); // 63

, *
, /
, ;
, .
, (
, )
, ,
, Math.floor
, function
or return
changes? Then your code is horribly broken.
%
)Simplified using ES6 Arrow function, and without dangerously extending the Number prototype
const mod = (n, m) => (n % m + m) % m;
console.log(mod(90, 360)); // 270 (Instead of 90)
If x
is an integer and n
is a power of 2, you can use x & (n  1)
instead of x % n
.
> 13 & (64  1)
51
Though it isn't behaving as you expected, it doesn't mean that JavaScript is not 'behaving'. It is a choice JavaScript made for its modulo calculation. Because, by definition either answer makes sense.
See this from Wikipedia. You can see on the right how different languages chose the result's sign.
This is not a bug, there's 3 functions to calculate modulo, you can use the one which fit your needs (I would recommend to use Euclidean function)
console.log( 41 % 7 ); // 6
console.log( 41 % 7 ); // 6
console.log( 41 % 7 ); // 6
console.log( 41 % 7 ); // 6
Number.prototype.mod = function(n) {
return ((this%n)+n)%n;
};
console.log( parseInt( 41).mod( 7) ); // 6
console.log( parseInt(41).mod( 7) ); // 1
console.log( parseInt(41).mod(7) ); // 6
console.log( parseInt( 41).mod(7) ); // 1
Number.prototype.mod = function(n) {
var m = ((this%n)+n)%n;
return m < 0 ? m + Math.abs(n) : m;
};
console.log( parseInt( 41).mod( 7) ); // 6
console.log( parseInt(41).mod( 7) ); // 1
console.log( parseInt(41).mod(7) ); // 1
console.log( parseInt( 41).mod(7) ); // 6
%
can return negative results (an this is the purpose of these functions, to fix it)
parseInt(41).mod(7)
would return 6
instead of 1
(and this is exactly the purpose of the Integer part function I wrote)
So it seems that if you're trying to mod around degrees (so that if you have 50 degrees  200 degrees), you'd want to use something like:
function modrad(m) {
return ((((180+m) % 360) + 360) % 360)180;
}
I deal with négative a and negative n too
//best perf, hard to read
function modul3(a,n){
r = a/n  0 ;
if(a < 0){
r += n < 0 ? 1 : 1
}
return a  n * r
}
// shorter code
function modul(a,n){
return a%n + (a < 0 && Math.abs(n));
}
//beetween perf and small code
function modul(a,n){
return a  n * Math[n > 0 ? 'floor' : 'ceil'](a/n);
}
There is a NPM package that will do the work for you. You can install it with the following command.
npm install justmodulo save
Usage copied from the README
import modulo from 'justmodulo';
modulo(7, 5); // 2
modulo(17, 23); // 17
modulo(16.2, 3.8); // 17
modulo(5.8, 3.4); //2.4
modulo(4, 0); // 4
modulo(7, 5); // 3
modulo(2, 15); // 13
modulo(5.8, 3.4); // 1
modulo(12, 1); // NaN
modulo(3, 8); // NaN
modulo(12, 'apple'); // NaN
modulo('bee', 9); // NaN
modulo(null, undefined); // NaN
GitHub repository can be found via the following link:
https://github.com/angusc/just/tree/master/packages/numbermodulo
For fun, here's a "wrap" function that works sorta like a modulo, except you can also specify the minimum value of the range (instead of it being 0):
const wrap = (value = 0, min = 0, max = 10) =>
((((value  min) % (max  min)) + (max  min)) % (max  min)) + min;
Basically just takes the true modulo formula, offsets it such that min
ends up at 0, then adds min
back in after.
Useful if you have a value that you want to keep between two values.
(13) % 64
or(13 % 64)
? Personally, I'd put in the parens either way, just for extra clarity.%
is not the modulo operator. It's the remainder operator. There is no modulo operator in JavaScript. So the accepted answer is the way to go.