How to calculate binomial coefficient modulo 142857 for large n
and r
. Is there anything special about the 142857? If the question is modulo p
where p
is prime then we can use Lucas theorem but what should be done for 142857.
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The algorithm is:
To compute Source: http://www.dms.umontreal.ca/~andrew/PDF/BinCoeff.pdf, theorem 1 define define define define define then 


You can actually calculate The trick is to calculate
Hence
We can calculate this easily In practice I would code it more implicit as follows:
This includes a Sieve of Eratosthenes, so the running time is 


What's special about 142857 is that 7 * 142857 = 999999 = 10^6  1. This is a factor that arises from Fermat's Little Theorem with a=10 and p=7, yielding the modular equivalence 10^7 == 10 (mod 7). That means you can work modulo 999999 for the most part and reduce to the final modulus by dividing by 7 at the end. The advantage of this is that modular division is very efficient in representation bases of the form 10^k for k=1,2,3,6. All you do in such cases is add together digit groups; this is a generalization of casting out nines. This optimization only really makes sense if you have hardware base10 multiplication. Which is really to say that it works well if you have to do this with paper and pencil. Since this problem recently appeared on an online contest, I imagine that's exactly the origin of the question. 


n
andr
? – Murilo Vasconcelos Oct 28 '12 at 5:37