I need a fast algorithm to evaluate the following

((a^n-1)/(a-1)) % p

Both a and n are nearly equal but less to 10^6 and p is a fixed prime number (let's say p=1000003). I need to compute it under 1 second. I am using python. Wolfram Mathematica computes it instantly. It takes 35.2170000076 seconds with following code

print (((10**6)**(10**6)-1)/((10**6)-1))%1000003

If that denominator a-1 were not present, I could group the powers into smaller order and use the relation a*b (mod c) = (a (mod c) * b (mod c)) (mod c) but denominator is present.

How to evaluate this with a fast algorithm? No numpy/scipy are available.

UPDATE:: Here is the final code I came up with

def exp_div_mod(a, n, p):
    r = pow(a, n, p*(a-1)) - 1
    r = r - 1 if r == -1 else r
    return r/(a-1)
  • 3
    you can use en.wikipedia.org/wiki/Extended_Euclidean_algorithm to find the inverse 1/(a-1) mod p; then apply the last identity you wrote. – hiro protagonist Jul 4 '15 at 13:14
  • @hiroprotagonist I'll try and let you know. – dread_cat_pirate Jul 4 '15 at 13:15
  • The gmpy module has a function that can compute modulus inverse: gmpy.divm "returns x such that b*x==a modulo m, or else raises a ZeroDivisionError exception if no such value x exists". With a, n & p as in the OP, (pow(a,n,p)-1)*gmpy.divm(1,a-1,p) % p returns 444446. – PM 2Ring Jul 4 '15 at 13:26
  • Of course, gmpy isn't necessary if you do a little bit of algebra, as in samgak's answer. :) – PM 2Ring Jul 4 '15 at 13:46
  • r = r - 1 if r == -1 else r in your update is wrong. – PM 2Ring Jul 7 '15 at 3:15

(((a ** n) - 1) / (a-1)) % p

can be rewritten as

(((a ** n) - 1) % ((a-1)*p)) / (a-1)

This part:

(((a ** n) - 1) % ((a-1)*p))

can be computed by calculating this:

((a ** n) % ((a-1)*p))

and then adjusting for the -1 afterwards.

Raise a by to the nth power and mod by ((a-1)*p). This can be done using the Python pow() function. Then adjust for the -1 and divide by a-1.

Using the pow() function and passing a modulo value is faster than computing the full exponent and then taking the modulo, because the modulo can be applied to the partial products at each stage of the calculation, which stops the value from getting too large (106 to the power of 106 has 6 million decimal digits, with a modulo applied at each step the values never have to grow larger than the size of the modulo - about 13 digits in this example).


def exp_div_mod(a, n, p):
    m = p * (a - 1)
    return ((pow(a, n, m) - 1) % m) // (a - 1);

print exp_div_mod((10**6), (10**6), 1000003)



Note: this approach only works if a, n and p are integers.

  • Nice! But you don't need that loop: the built-in Python pow function takes a modulus as an optional 3rd argument. So you can do m = p * (a - 1); x = ((pow(a, n, m) - 1) % m) // (a - 1) – PM 2Ring Jul 4 '15 at 13:40
  • 2
    @NiklasB.: Why won't it work? Note that ((a ** n) - 1) / (a-1) is an integer (the sum of a geometric progression). Let q/b be an integer, with q/b = k*p + r. Then q=k*(p*b)+(r*b) – PM 2Ring Jul 4 '15 at 14:06
  • 1
    @NiklasB. FWIW, I just tested samgak's algorithm against (a**n - 1) / (a - 1)) % p for 10000 randomly chosen 1 < a, n, p <10000, with p prime. There were no failures. – PM 2Ring Jul 4 '15 at 14:39
  • 1
    Nevermind, I didn't read the answer properly. Nice trick extending the modulus, pretty clever :) – Niklas B. Jul 4 '15 at 14:58
  • You could also shorten the second to last lines of your function to return (pow(a, n, m) - 1) % m / (a-1), but that's just a matter of preference – Niklas B. Jul 4 '15 at 15:03

(an−1) ⁄ (a−1) is the sum from i = 0 to n−1 of ai.

Computing the latter mod p is straightforward, based on the following:

let F(a, n) be Σ(i=0..n-1){ai} if n > 0, otherwise 0.


  1. F(a,n) = a×F(a,n−1) + 1

  2. F(a,2n) = (a+1)×F(a2,n)

The second identity is the divide-and-conquer recursion.

Since both of these only involve addition and multiplication, we can compute them mod p without needing an integer type larger than a×p by distributing the modulus operation. (See code below.)

With just the first recursion, we can code an iterative solution:

def sum_of_powers(a, n, p):
  sum = 0
  for i in range(n): sum = (a * sum + 1) % p
  return sum

Using the divide-and-conquer recursion as well, we arrive at something not much more complicated:

def sum_of_powers(a, n, p):
  if n % 2 == 1:
    return (a * sum_of_powers(a, n-1, p) + 1) % p
  elif n > 0:
    return ((a + 1) * sum_of_powers(a * a % p, n // 2, p)) % p
    return 0

The first solution returns in less than a second with n == 106. The second one returns instantly, even with n as large as 109.

  • Can you do it without a loop? Summing a million or so mod powers in a loop isn't exactly fast. – PM 2Ring Jul 4 '15 at 14:40
  • @PM2Ring There is a trick where you seperate the odd and even terms and reuse the sum of even summands to compute the sum of the odd ones in O(1), yielding an algorithm that uses only O(log n) additions and multiplications – Niklas B. Jul 4 '15 at 15:05
  • @pm2ring: if you sum a^i%p startimg with i=0, each term requires "only" a multiply and a mod (by taking advantage of the value of the previous term); you never need to compute a power. A million such computations can be done easily in a second on modern hardwaree. But NiklasB's suggestion is even faster – rici Jul 4 '15 at 15:16
  • @NiklasB. Interesting! I think I see how that divide-and-conquer approach would work in O(log n). – PM 2Ring Jul 4 '15 at 15:28
  • @rici trust me, I tried this before I posted answer question here. I considered the method proposed by Nicholas B but found it too much to code it up. – dread_cat_pirate Jul 4 '15 at 15:28

You can multiply by the modular inverse of p - 1. Due to Fermat's little theorem, you have xp-2 · x ≡ xp-1 ≡ 1 (mod p) for all 0 < x < p, so you don't even need extended Euclid to compute the inverse, just the pow function from standard Python:

(pow(a, n, p) - 1) * pow(a - 1, p - 2, p) % p

The algorithm has time complexity 𝒪(log p) because square-and-multiply is used.

  • I guess you mean the inverse of a-1, not p-1. – Mark Dickinson Jul 4 '15 at 13:59
  • Hi, I don't understand your first approach, could you write some math for it? I am aware of Fermat's theorem, but after it ?? – dread_cat_pirate Jul 4 '15 at 15:06
  • 1
    @dread_cat_pirate You can divide by a number x modulo a prime by multiplying with the modular inverse x^(-1). Typically you would use extended Euclid's algorithm to compute the inverse, but in the case of a prime modulus the inverse is just x^(p-2), due to Fermat's theorem – Niklas B. Jul 4 '15 at 15:09
  • I understand the other answer, but still, I am not getting it mathematically. x is the modular inverse of x^(p-2) due to Fermat, but how is this relation true? – dread_cat_pirate Jul 4 '15 at 15:23
  • Pity we can't use LaTeX here, like on SE.Mathematics... – PM 2Ring Jul 4 '15 at 15:33

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