In modular arithmetic, one defines *classes* of numbers based on the modulo. In other words, in modulo *m* arithmetic, a number *n* is equivalent (== the same) to *n* + *m*, *n* - *m*, *n* + *2m*, *n* - *2m*... etc.

One defines *m* "baskets", and every number falls in one (and only one) of them.

**Example**: one can say "It's 4:30pm" or one can say "It's 16:30". Both forms mean exactly the same time, but are different *representations* of it.

Thus — both the python and C# results are correct! The numbers are *the same* in the modulo *5* arithmetic you chose. It would also have been *mathematically* correct to return (5, 6, 7, 8, 9) for example. Just a bit odd.

As for the choice of representation (in other words, the choice on how to represent negative numbers), that is just a case of different design choices between the two languages.

However, that is not at all what the % operator actually does in C#. The % operator is not the canonical modulus operator, it is the remainder operator. The A % B operator actually answer the question "If I divided A by B using integer arithmetic, what would the remainder be?"

— *What's the difference? Remainder vs Modulus* by Eric Lippert

Quick snippet to get the canonical modulus

```
return ((n % m) + m) % m;
```

Test:

```
imac:~ sklivvz$ cat mod.cs
using System;
public class Program
{
public static void Main (string[] args)
{
Console.WriteLine(Mod(-2, 5));
Console.WriteLine(Mod(-5, 5));
Console.WriteLine(Mod(-2, -5));
}
public static int Mod (int n, int m)
{
return ((n % m) + m) % m;
}
}
imac:~ sklivvz$ mono mod.exe
3
0
-2
imac:~ sklivvz$ cat mod.py
print -2%5;
print -5%5;
print -2%-5;
imac:~ sklivvz$ python mod.py
3
0
-2
```

remainderoperator. Eric Lippert explains. – Raymond Chen Apr 8 '12 at 18:08