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# Euclidean algorithm to solve RR' - NN' = 1. Modular exponentiation with Montgomery algorithm to implement Fermat test in python or Petite Chez scheme

This is as a personal challenge in my introductory programming class taught using Scheme, but I would be equally happy with Python examples.

I've already implemented the binary method of modular exponentiation in scheme as follows:

``````(define (pow base expo modu)
(if (zero? expo)
1
(if (even? expo)
(mod (expt (pow base (/ expo 2) modu) 2) modu)
(mod (* base (pow base (sub1 expo) modu)) modu))))
``````

This is necessary as Chez Scheme doesn't have any implementation similar to python's pow (base expo modu).

Now I am trying to implement the Montgomery method of solving modular multiplication. As an example, I have:

``````Trying to solve:
(a * b) % N
N = 79
a = 61
b = 5
R = 100
a' = (61 * 100) % 79 = 17
b' = (5 * 100) % 79 = 26
RR' - NN' = 1
``````

I'm trying to understand how to solve RR' - NN' = 1. I realize that the answer to R' should be 64 and N' should be 81, but don't understand how to use the Euclidean Algorithm to get this answer.

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The extended Euclidean algorithm is:

``````(define (euclid x y)
(let loop ((a 1) (b 0) (g x) (u 0) (v 1) (w y))
(if (zero? w) (values a b g)
(let ((q (quotient g w)))
(loop u v w (- a (* q u)) (- b (* q v)) (- g (* q w)))))))
``````

Thus, on your example,

``````> (euclid 79 100)
19
-15
1
``````

You can read more at my blog.

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