# Can someone please explain the use of modulus in this code?

I know that modulus gives the remainder and that this code will give the survivor of the Josephus Problem. I have noticed a pattern that when n mod k = 0, the starting count point begins at the very beginning of the circle and that when n mod k = 1, the person immediately before the beginning of the circle survived that execution round through the circle.

I just don't understand how this recursion uses modulus to find the last man standing and what josephus(n-1,k) is actually referring to. Is it referring to the last person to get executed or the last survivor of a specific round through the circle?

`````` def josephus( n, k):
if n ==1:
return 1
else:
return ((josephus(n-1,k)+k-1) % n)+1
``````
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Do you understand what the josephus problem is? Basically the modulus is to wrap the index into a circle around to stay within the circle. –  GuyGreer Feb 12 '14 at 19:38
@GuyGreer, could you please expand on wrapping the index into a circle? I don't understand what that is supposed to accomplish. And what is each recursion step supposed to represent? –  Jay Feb 12 '14 at 19:42
I have a buffer `{0,1,2,3,4,5,6}`, which represents a circle (so that `1` and `6` are in fact adjacent). If my index is `4` and I add `5` to it to get `9`, that seems outside the circle, so by taking the modulus `9 % 7 == 2` I get the index into my buffer of `2` and I can continue happily going around in circles. –  GuyGreer Feb 12 '14 at 19:50
Did you mean `0` and `6` are adjacent? –  KodeSeeker Aug 16 '14 at 21:52

This answer is both a summary of the Josephus Problem and an answer to your questions of:

1. What is `josephus(n-1,k)` referring to?
2. What is the modulus operator being used for?

When calling `josephus(n-1,k)` that means that you've executed every kth person up to a total of n-1 times. (Changed to match George Tomlinson's comment)

The recursion keeps going until there is 1 person standing, and when the function returns itself to the top, it will return the position that you will have to be in to survive. The modulus operator is being used to help stay within the circle (just as GuyGreer explained in the comments). Here is a picture to help explain:

`````` 1 2
6   3
5 4
``````

Let the n = 6 and k = 2 (execute every 2nd person in the circle). First run through the function once and you have executed the 2nd person, the circle becomes:

`````` 1 X
6   3
5 4
``````

Continue through the recursion until the last person remains will result in the following sequence:

`````` 1 2      1 X      1 X      1 X      1 X      X X
6   3 -> 6   3 -> 6   3 -> X   3 -> X   X -> X   X
5 4      5 4      5 X      5 X      5 X      5 X
``````

When we check the values returned from josephus at n we get the following values:

``````n = 1 return 1
n = 2 return (1 + 2 - 1) % 2 + 1 = 1
n = 3 return (1 + 2 - 1) % 3 + 1 = 3
n = 4 return (3 + 2 - 1) % 4 + 1 = 1
n = 5 return (1 + 2 - 1) % 5 + 1 = 3
n = 6 return (3 + 2 - 1) % 6 + 1 = 5
``````

Which shows that josephus(n-1,k) refers to the position of the last survivor. (1)

If we removed the modulus operator then you will see that this will return the 11th position but there is only 6 here so the modulus operator helps keep the counting within the bounds of the circle. (2)

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Ok, I probably didn't need to mention it actually. Sorry if I caused any offence. –  George Tomlinson Feb 13 '14 at 14:50
It wasn't in anyway offensive, :). I just like to improve my answer, even if it's already accepted. –  John Odom Feb 13 '14 at 15:43
Actually, it now sounds like each person is executed n-1 times! Probably better to say 'When calling josephus(n-1,k) that means that every kth person is executed up to a total of n-1 people.' It still sounds a bit clumsy, but it's the best I can think of at present and at least it makes sense. –  George Tomlinson Feb 13 '14 at 16:46
@GeorgeTomlinson When you say "each person is executed n-1 times" It makes me think that one person is being executed n-1 times. I didn't know you can die more than one time, lol. But your second sentence sounds better. –  John Odom Feb 13 '14 at 17:11

To answer your second question, it's referring to the position of the last survivor.

Consider j(4,2).

Using the algorithm gives

``````j(4,2)=(j(3,2)+1)%4)+1
j(3,2)=(j(2,2)+1)%3)+1
j(2,2)=(j(1,2)+1)%2)+1
j(1,2)=1
``````

and so

``````j(2,2)=((1+1)%2)+1=1
j(3,2)=((1+1)%3)+1=3
j(4,2)=((3+1)%4)+1=1
``````

Now the table of j(2,2) is

``````1 2
1 x
``````

so j(2,2) is indeed 1.

For j(3,2) we have

``````1 2 3
1 x 3
x x 3
``````

so j(3,2) is 3 as required.

Finally, j(4,2) is

``````1 2 3 4
1 x 3 4
1 x 3 x
1 x x x
``````

which tells us that j(4,2)=1 as required.

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