# .NET method to round a number up to the nearest multiple of another number?

I'm looking for a method that can round a number up to the nearest multiple of another. This is similar Quantization.

Eg. If I want to round 81 up to the nearest multiple of 20, it should return 100.

Is there a method built-in method in the .NET framework I can use for this?

The reason I'm asking for a built-in method is because there's a good chance it's been optimized already.

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Yes, integer arithmetic.

To round m up to the next multiple of n, use ((m+n-1)/n)*n

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As long as n != 0 of course. –  Jason Lepack Dec 19 '08 at 13:33
Also, the "next multiple" of a negative number is actually rounding down. –  Jason Lepack Dec 19 '08 at 13:35
True enough, but the OP needs to do some of the work :) –  Joe Dec 19 '08 at 15:34
You seemed to have missed the part where I asked for a "built-in" method. –  ilitirit Dec 19 '08 at 21:24
To put it a little more mnemonically: To round the number n up to the next multiple of m, use `((n+m-1)/m)*m`. –  martineau Jan 8 '12 at 3:44
``````public static int RoundUp(int num, int multiple)
{
if (multiple == 0)
return 0;
int add = multiple / Math.Abs(multiple);
return ((num + multiple - add) / multiple)*multiple;
}

static void Main()
{
Console.WriteLine(RoundUp(5, -2));
Console.WriteLine(RoundUp(5, 2));
}

/* Output
* 4
* 6
*/
``````
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Lee's answer is good but it should have been:

``````t = m + n - 1; return (t - (t % m));
``````

Notice the change from `N` to `M`. The modulo operation should be done with the multiplier `(m)` and not with the number `(n)`.

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Good catch. Things got confusing as soon as people starting using 'm' for the number and 'n' for the multiple -- which seems counter-intuitive at best. –  martineau Jan 8 '12 at 4:19

If you're using a lot of these on a relatively slow platform, you may eliminate the multiplication by using a variant of:

t = m + n - 1; return (t - (t % n));

Of course, if you can limit your multiple to values of 2^n, then the modulus operation may also be deprecated in favour of its logical equivalent (usually "&").

Incidentally, the "RoundUp" function illustrated above is seriously flawed and will only round down correctly when {(m % n) == (n - 1)}; rounding down is implicit for integer division and as such, does not require compensation.

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