# How to calculate the Modular Multiplicative inverse of a number in the context of RSA encryption?

How to calculate the Modular Multiplicative inverse of a number in the context of RSA encryption?

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Use the Extended Euclidean Algorithm, which is significantly faster than direct modular exponentiation in practice.

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Direct Modular Exponentiation

The direct modular exponentiation method, as an alternative to the extended Euclidean algorithm, is as follows:

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This method requires the order of the group in which you take the inverse. In the case of RSA you usually don't know this. –  abc Jul 28 '10 at 9:20
You know it if the modulus is prime - it's P-1. For an RSA key at the time of key generation you may know it as well (P-1)*(Q-1). Once the key pairs are created, the factorization of the modulus is thrown away, as knowing the order of the group is required to create a key pair and is equivalent to finding the private key. –  phkahler Jul 28 '10 at 13:47
Since in RSA, to find the private key you need to find the inverse of `e (mod φ(n))`, using this method requires you to calculate `φ(φ(n))`, which is equivalent to factoring `φ(n)`. So, @abc is right: you can't use this method; I did not even think about this earlier. –  BlueRaja - Danny Pflughoeft Jul 28 '10 at 21:23
It's easy to compute phi(phi(n)) if the RSA primes are safe primes. See my comment to stackoverflow.com/questions/3209665/…. But it's just fun to think about and tinker with, the extended euclidean algorithm always works fast. –  GregS Jul 29 '10 at 0:03

There are two algorithms explained in detail in the Modular multiplicative inverse Wikipedia article.

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If You need to calculate `w` for DSA alghoritm, you can use this:

``````w = s^-1 mod q
``````

is actually

``````w = s^(q-2) mod q
``````
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I worked out a an simpler inverse function

``````def privateExponent(p,q,e):
totient=(p-1)*(q-1)
for k in range(1,e):
if (totient*k+1) % e==0:
return (totient*k+1)/e
return -1 # shouldnt get here
``````

The equation d*e=1 (mod totient) can be rewritten as d*e=1+k*totient (for some value of k) and the program just searches for first value of k which makes the equation divisible by e (the public exponent). This will work if e is small (as is usually recommended).

We can move all the bignum operations out of the loop to improve its performance.

``````def privateExponent(p,q,e):
totient=(p-1)*(q-1)
t_mod_e=totient % e
k=0
total=1
while total!=0:
k+=1
total=(total+t_mod_e) % e
return (k*totient+1)/e
``````

It turns out that for e=3, we don't really have to search as the answer is always 2*((p-1)*(q-1)+1)/3

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