I was solving `nCr%m`

for big `n`

(~`10**9`

) and non-prime `m`

(`142857 = 3^3*11*13*37`

).

So I used generalised **Lucas Theorem** to get the prime power factors of `m`

, and then solve them by **Chinese Remainder Theorem**.

I am almost there, but the generalised Lucas Theorem states something about `e_q`

. But I am not sure about what is `e_q`

and how to calculated easily. What I thought about `e_q`

is, it is `e_0`

for `floor(n/p^q)`

and `floor(r/p^q)`

. But it is giving wrong outputs and they are correct outputs but with opposite sign. I understood what is `e_0`

for `n`

and `r`

and can be easily calculated from the power of `p`

in `n!`

, `r!`

and `(n-r)!`

.

I guess, my rest of my code are fine, because `e_q`

is on the power of `-1`

and the wrong outputs are the correct outputs with opposite sign. I just need to find out the correct `e_q`

.

Needless to say, It does not give wrong output always.

Anyone to help me to find out `e_q`

?

EDIT : I HAVE SUCCESSFULLY SOLVED THIS PROBLEM ! Thanks for all of your responses !

`e_q`

is on the power of`-1`

" but the linked description actually has`+/-1`

and a note below specifying which to use. – Ben Jackson Jul 28 '13 at 20:35`m = 142857 = 3^3*11*13*37`

. Using original Lucas Theorem, I solved one powered prime cases easily. But the problem arose, when I used generalised Lucas theorem for`3^3`

. It is only`e_q`

where the code glitches ! – rnbcoder Jul 28 '13 at 20:36