n can be arbitrarily large

Well, `n`

can't be *arbitrarily* large - if `n >= m`

, then `n! ≡ 0 (mod m)`

*(because *`m`

is one of the factors, by the definition of factorial).

Assuming `n << m`

and you need an *exact* value, your algorithm can't get any faster, to my knowledge. However, if `n > m/2`

, you can use the following identity *(Wilson's theorem - Thanks @Daniel Fischer!)*

to cap the number of multiplications at about `m-n`

(m-1)! ≡ -1 (mod m)
1 * 2 * 3 * ... * (n-1) * n * (n+1) * ... * (m-2) * (m-1) ≡ -1 (mod m)
n! * (n+1) * ... * (m-2) * (m-1) ≡ -1 (mod m)
n! ≡ -[(n+1) * ... * (m-2) * (m-1)]^{-1} (mod m)

This gives us a simple way to calculate `n! (mod m)`

in `m-n-1`

multiplications, plus a modular inverse:

def factorialMod(n, modulus):
ans=1
if n <= modulus//2:
#calculate the factorial normally (right argument of range() is exclusive)
for i in range(1,n+1):
ans = (ans * i) % modulus
else:
#Fancypants method for large n
for i in range(n+1,modulus):
ans = (ans * i) % modulus
ans = modinv(ans, modulus)
ans = -1*ans + modulus
return ans % modulus

We can rephrase the above equation in another way, that may or may-not perform slightly faster. Using the following identity:

we can rephrase the equation as

n! ≡ -[(n+1) * ... * (m-2) * (m-1)]^{-1} (mod m)
n! ≡ -[(n+1-m) * ... * (m-2-m) * (m-1-m)]^{-1} (mod m)
(reverse order of terms)
n! ≡ -[(-1) * (-2) * ... * -(m-n-2) * -(m-n-1)]^{-1} (mod m)
n! ≡ -[(1) * (2) * ... * (m-n-2) * (m-n-1) * (-1)^{(m-n-1)}]^{-1} (mod m)
n! ≡ [(m-n-1)!]^{-1} * (-1)^{(m-n)} (mod m)

This can be written in Python as follows:

def factorialMod(n, modulus):
ans=1
if n <= modulus//2:
#calculate the factorial normally (right argument of range() is exclusive)
for i in range(1,n+1):
ans = (ans * i) % modulus
else:
#Fancypants method for large n
for i in range(1,modulus-n):
ans = (ans * i) % modulus
ans = modinv(ans, modulus)
#Since m is an odd-prime, (-1)^(m-n) = -1 if n is even, +1 if n is odd
if n % 2 == 0:
ans = -1*ans + modulus
return ans % modulus

If you don't need an *exact* value, life gets a bit easier - you can use Stirling's approximation to calculate an approximate value in `O(log n)`

time *(using exponentiation by squaring)*.

Finally, I should mention that if this is time-critical and you're using Python, try switching to C++. From personal experience, you should expect about an order-of-magnitude increase in speed or more, simply because this is exactly the sort of CPU-bound tight-loop that natively-compiled code *excels* at *(also, for whatever reason, GMP seems much more finely-tuned than Python's Bignum)*.

`n`

? – Matti Virkkunen Mar 15 '12 at 20:52