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I was curious if there was a good way to do this. My current code is something like:

def factorialMod(n, modulus):
    for i in range(1,n+1):
        ans = ans * i % modulus    
    return ans % modulus

But it seems quite slow!

I also can't calculate n! and then apply the prime modulus because sometimes n is so large that n! is just not feasible to calculate explicitly.

I also came across http://en.wikipedia.org/wiki/Stirling%27s_approximation and wonder if this can be used at all here in some way?

Or, how might I create a recursive, memoized function in C++?

share|improve this question
How big is n? – Matti Virkkunen Mar 15 '12 at 20:52
Arbitrarily large – John Smith Mar 15 '12 at 20:52
How slow is slow? From your pseudocode, I infer you're computing this in Python, is that right? – Fred Foo Mar 15 '12 at 20:56
There's a very fast way to do this using invariant multiplication or possibly Montgomery reduction. Both methods eliminate the modulus and will allow for loop-unrolling techniques. – Mysticial Mar 15 '12 at 21:25
You can break down modulus into prime factors to identify cases that will be zero more easily, although that won't help for large prime factors - how helpful this is depends on what you know about the modulus, if anything, and if prime factorisation tickles your fancy. – davin Mar 15 '12 at 21:26
up vote 13 down vote accepted

Expanding my comment to an answer:

Yes, there are more efficient ways to do this. But they are extremely messy.

So unless you really need that extra performance, I don't suggest to try to implement these.

The key is to note that the modulus (which is essentially a division) is going to be the bottleneck operation. Fortunately, there are some very fast algorithms that allow you to perform modulus over the same number many times.

These methods are fast because they essentially eliminate the modulus.

Those methods alone should give you a moderate speedup. To be truly efficient, you may need to unroll the loop to allow for better IPC:

Something like this:

ans0 = 1
ans1 = 1
for i in range(1,(n+1) / 2):
    ans0 = ans0 * (2*i + 0) % modulus    
    ans1 = ans1 * (2*i + 1) % modulus    

return ans0 * ans1 % modulus

but taking into account for an odd # of iterations and combining it with one of the methods I linked to above.

Some may argue that loop-unrolling should be left to the compiler. I will counter-argue that compilers are currently not smart enough to unroll this particular loop. Have a closer look and you will see why.

Note that although my answer is language-agnostic, it is meant primarily for C or C++.

share|improve this answer
It might be nice to get a comment from whoever just downvoted the 3 top ansewrs. – Mysticial Mar 15 '12 at 22:07
How might recursion + memoization be done in C++ for factoral mod m? – John Smith Mar 15 '12 at 22:18
@JohnSmith TBH, Memoization is probably not going to help at all - there's nothing to memoize. The only way it might become helpful is if you try the prime-factorization approach and use the windowing algorithm for exponentiation by squaring. (The windowing algorithm is a memoization algorithm.) But prime factorizing all integers from 1 to n will probably be slower than your current algorithm. – Mysticial Mar 15 '12 at 22:22
Well in my case I am iterating from low n to high n, so doesn't that mean I can save time by storing values I've already calculated? For large n it seems like it'd save a lot of time by only doing a couple iterations rather than go from i=1 to n or n/2 – John Smith Mar 15 '12 at 22:23
Well... There's nothing to "save". Knowing a couple iterations won't help you with the rest of them. – Mysticial Mar 15 '12 at 22:27

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):
    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   
        #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):
    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   
        #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).

share|improve this answer
"Thus, when m/2 < n < m, you only need to calculate (m/2)! * (-2)^(n-m/2-1) (mod m)" You can do better then. By Wilson's theorem, (m-1)! ≡ -1 (mod m) if m is prime. Now (m-1)! = n! * (m - (m-n-1)) * ... * (m - 1) ≡ (-1)^(m-n-1) * n! * (m-n-1)! (mod m), so n! ≡ (-1)^(m-n) * ((m-n-1)!)^(-1) (mod m). So you need to calculate (m-n-1)! mod m, find its modular inverse (O(log m) steps), and adjust the sign if necessary. Not much difference when n is close to m/2, but nice when n > 3m/4 or so. – Daniel Fischer Mar 16 '12 at 10:54
@DanielFischer: Thanks! I've included that in the answer. – BlueRaja - Danny Pflughoeft Mar 16 '12 at 18:37

n! mod m can be computed in O(n1/2 + ε) operations instead of the naive O(n). This requires use of FFT polynomial multiplication, and is only worthwhile for very large n, e.g. n > 104.

An outline of the algorithm and some timings can be seen here: http://fredrikj.net/blog/2012/03/factorials-mod-n-and-wilsons-theorem/

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If we want to calculate M = a*(a+1) * ... * (b-1) * b (mod p), we can use the following approach, if we assume we can add, substract and multiply fast (mod p), and get a running time complexity of O( sqrt(b-a) * polylog(b-a) ).

For simplicity, assume (b-a+1) = k^2, is a square. Now, we can divide our product into k parts, i.e. M = [a*..*(a+k-1)] *...* [(b-k+1)*..*b]. Each of the factors in this product is of the form p(x)=x*..*(x+k-1), for appropriate x.

By using a fast multiplication algorithm of polynomials, such as Schönhage–Strassen algorithm, in a divide & conquer manner, one can find the coefficients of the polynomial p(x) in O( k * polylog(k) ). Now, apparently there is an algorithm for substituting k points in the same degree-k polynomial in O( k * polylog(k) ), which means, we can calculate p(a), p(a+k), ..., p(b-k+1) fast.

This algorithm of substituting many points into one polynomial is described in the book "Prime numbers" by C. Pomerance and R. Crandall. Eventually, when you have these k values, you can multiply them in O(k) and get the desired value.

Note that all of our operations where taken (mod p). The exact running time is O(sqrt(b-a) * log(b-a)^2 * log(log(b-a))).

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The algorithm of "substituting many points into one polynomial" is described also in the well known book "introduction to algorithms" by H. Cormen and others (in the FFT chapter). – ohad Oct 7 '14 at 17:22

Expanding on my comment, this takes about 50% of the time for all n in [100, 100007] where m=(117 | 1117):

Function facmod(n As Integer, m As Integer) As Integer
    Dim f As Integer = 1
    For i As Integer = 2 To n
        f = f * i
        If f > m Then
            f = f Mod m
        End If
    Return f
End Function
share|improve this answer

If n = (m - 1) for prime m then by http://en.wikipedia.org/wiki/Wilson's_theorem n! mod m = (m - 1)

Also as has already been pointed out n! mod m = 0 if n > m

share|improve this answer
This is not helpful. BlueRaja-Danny-Pflughoeft already mentioned Wilson's theorem, and it doesn't do much because you can't count on needing just (m-1)!, or (m-k)! for small k, which his answer covered but yours didn't. – Douglas Zare Apr 4 '15 at 19:23

Assuming that the "mod" operator of your chosen platform is sufficiently fast, you're bounded primarily by the speed at which you can calculate n! and the space you have available to compute it in.

Then it's essentially a 2-step operation:

  1. Calculate n! (there are lots of fast algorithms so I won't repeat any here)
  2. Take the mod of the result

There's no need to complexify things, especially if speed is the critical component. In general, do as few operations inside the loop as you can.

If you need to calculate n! mod m repeatedly, then you may want to memoize the values coming out of the function doing the calculations. As always, it's the classic space/time tradeoff, but lookup tables are very fast.

Lastly, you can combine memoization with recursion (and trampolines as well if needed) to get things really fast.

share|improve this answer
however, for large n, calculating n! and then performing mod is not feasible – John Smith Mar 15 '12 at 21:00
Not feasible...why? Due to memory constraints? From the question, speed was the issue, not memory. If you are looking to have as small a memory footprint as possible and then optimize for speed, please update your question to reflect this. – cdeszaq Mar 15 '12 at 21:01
-1 Computing n! and then mod is very slow, please try to compute 2000000! mod 5250307 that way. OP is doing it better in the question, you should interleave multiplication and taking modulo. – sdcvvc Mar 15 '12 at 21:07
@cdeszaq: What you seem to be missing is that multiplying two extremely large numbers (larger than the size of a register) is not O(1) on a computer: it's closer to O(m log m) (m = #bits). Multiplying two m-bit numbers results in (m+m)-bits, so your method takes approximately m log(m) + 2m log(m) + 3m log(m) + ... + nm log(m) = nm log(m)(n+1)/2 = O(mn^2 log(m)) operations. Taking a modulus after each operation, however, would result in about 2(m log (m)) + 2(m log(m)) + ...n additions... + 2(m log(m)) = 2mn log(m) = O(mn log(m)) which is significantly faster, even for small n. – BlueRaja - Danny Pflughoeft Mar 15 '12 at 22:15
Computing n! for very large n is not only slow, but quite impossible because the numbers get so large you can't address them any more. – Bogdan Alexandru Apr 22 '15 at 9:19

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