# 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? – biziclop Jan 30 '11 at 21:06
• @biziclop - isn't it rather obvious it belongs to the last one...? – IVlad Jan 30 '11 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 '11 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. – IVlad Jan 30 '11 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. – IVlad Jan 30 '11 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? – noooooooob Feb 27 '14 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. – biziclop Mar 4 '14 at 11:46