# extended euclidean algorithm and the concept of multiplicative inverse

I have with python:

``````e*d == 1%etf
``````

we know (e) and (etf) and must discover (d) using the extended euclidean algorithm and the concept of multiplicative inverse of modular arithmetic.

``````d = (1/e)%etf

d = (e**-1)%etf
``````

The solution (Modular multiplicative inverse function in Python) illustrated below gives me wrong computational result

``````e*d == 1 (mod etf)
d = (e**(etf-2)) % etf
d = pow(e,etf-2,etf)
``````

Am I making some mistake elsewhere? Is this calculation ok?

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I gave an implementation of the extended Euclidean algorithm in an answer to a separate question: stackoverflow.com/a/11703184 –  Luke Woodward Sep 20 '12 at 19:30
Well @woodward in a firt look inward your function I see only 1 parameter of input. To calculate d I suppose is necessary know the variables etf and e, since the problem is ( d*e == 1 % etf ). –  iuri Sep 21 '12 at 19:27
d = pow(e,etf-2,etf) only works when etf is prime. –  phkahler Sep 21 '12 at 22:09

Here's an implementation of the extended Euclidean algorithm. I've taken the code from this answer, generalised it so that it works with moduli other than 262, and converted it from Java to Python:

``````def multiplicativeInverse(x, modulus):
if modulus <= 0:
raise ValueError("modulus must be positive")

a = abs(x)
b = modulus
sign = -1 if x < 0 else 1

c1 = 1
d1 = 0
c2 = 0
d2 = 1

# Loop invariants:
# c1 * abs(x) + d1 * modulus = a
# c2 * abs(x) + d2 * modulus = b

while b > 0:
q = a / b
r = a % b
# r = a - qb.

c3 = c1 - q*c2
d3 = d1 - q*d2

# Now c3 * abs(x) + d3 * modulus = r, with 0 <= r < b.

c1 = c2
d1 = d2
c2 = c3
d2 = d3
a = b
b = r

if a != 1:
raise ValueError("gcd of %d and %d is %d, so %d has no "
"multiplicative inverse modulo %d"
% (x, modulus, a, x, modulus))

return c1 * sign;
``````
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The trick you list with `d = (e**(etf-2)) % etf` will work only if etf is prime. If it's not, you have to use the EEA itself to find the modular multiplicative inverse.