# Josephus for large n (Facebook Hacker Cup)

Last week I participated in round 1b of the Facebook Hacker cup.

One of the problems was basically the Josephus problem

I've studied the Josephus problem before as a discrete math problem, so I basically understand how to get the recurrence:

``````f(n,k) = (f(n-1,k) + k) mod n, with f(1,k) = 0
``````

But that didn't work in the Facebook Hacker Cup, because the max value of n was 10^12. The mak value of k was 10^4.

Wikipedia mentions an approach when k is small and n is large. Basically remove people from a single round, and then renumber. But it's not described much and I don't understand why the renumbering works.

I looked at sample working source code for the solution, but I still don't understand that final portion.

``````long long joseph (long long n,long long k) {
if (n==1LL) return 0LL;
if (k==1LL) return n-1LL;
if (k>n) return (joseph(n-1LL,k)+k)%n;
long long cnt=n/k;
long long res=joseph(n-cnt,k);
res-=n%k;
if (res<0LL) res+=n;
else res+=res/(k-1LL);
return res;
}
``````

The part I really don't understand is starting from `res-=n%k` (and the lines thereafter). How do you derive that that is the way to adjust the result?

Could someone show the reasoning behind how this is derived? Or a link that derives it? (I didn't find any info on UVA or topcoder forums)

• Which `if` does the last `else` belong to? Jan 30, 2011 at 21:06
• @biziclop - isn't it rather obvious it belongs to the last one...? Jan 30, 2011 at 21:14
• @IVlad: Isn't it obvious to you that if the question has to be asked the code suffers from lack of clarity?
– JimR
Jan 30, 2011 at 21:36
• @JimR - The logic behind the code is indeed not clear, but that's what the question is about, so it can't be helped. The syntax however is very clear. Jan 30, 2011 at 21:40
• @JimR - actually, I have about 5 years experience working with this type of algorithm-competition code. It might be a bit cryptic and not follow the best industry standards, but I can assure you it's correct and written as it is intended to work, because it is the official (or at least a correct) solution to the given problem. I apologize to @biziclop if my question sounded rude or anything, that was not my intention. I just meant to emphasize that the code works, and the question is about why it works. Jan 30, 2011 at 21:46

Right, I think I cracked it.

Let's look at how the iterations go with n=10, k=3:

``````0 1 2 3 4 5 6 7 8 9    n=10,k=3
1 2   3 4   5 6   0    n=7,k=3
``````

Observe how the elements of the second iteration map to the first one: they are transposed by `n%k`, because the circle wraps around. That's why we correct the result by subtracting `10%3`. The numbers in the second row appear in groups of `k-1`, hence the correction by `res/(k-1)`.

The other case is hit further along the iterations

``````0 1 2 3 4     n=5,k=3
2 3   0 1     n=4,k=3
``````

Now j(4,3) returns 0, which corrected by `5%3` turns out to be -2. This only happens if the result of the second row is in the last group, in which case adding `n` to the result will give us our original index.

• May I ask what's the complexity of this algorithm? Even faster than O(n)? so O(logn) I suppose? Feb 27, 2014 at 11:15
• I didn't invent the algorithm so I'm not entirely certain but Wikipedia claims it's O(k*logn), which looks about right. Mar 4, 2014 at 11:46