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I've written the code for multiplicative inverse of modulo m. It works for most of the initial cases but not for some. The code is below:

(define (inverse x m)
    (let loop ((x (modulo x m)) (a 1))
      (cond ((zero? x) #f) ((= x 1) a)
            (else (let ((q (- (quotient m x))))
                    (loop (+ m (* q x)) (modulo (* q a) m)))))))

For example it gives correct values for (inverse 5 11) -> 9 (inverse 9 11) -> 5 (inverse 7 11 ) - > 8 (inverse 8 12) -> #f but when i give (inverse 5 12) it produces #f while it should have been 5. Can you see where the bug is?

Thanks for any help.

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What algorithm are you using? –  Barmar Oct 27 '12 at 2:07
    
cdsmith.wordpress.com/2009/07/20/… this one –  new user Oct 27 '12 at 2:10
    
I'm having a hard time finding the correspondences between the algorithm presented there and your code. It doesn't help that it uses p and q, while you use x and m (and q that doesn't correspond to their q). –  Barmar Oct 27 '12 at 2:30

4 Answers 4

up vote 1 down vote accepted

Does it have to be precisely that algorithm? if not, try this one, taken from wikibooks:

(define (egcd a b)
  (if (zero? a)
      (values b 0 1)
      (let-values (((g y x) (egcd (modulo b a) a)))
        (values g (- x (* (quotient b a) y)) y))))

(define (modinv a m)
  (let-values (((g x y) (egcd a m)))
    (if (not (= g 1))
        #f
        (modulo x m))))

It works as expected:

(modinv 5 11) ; 9
(modinv 9 11) ; 5
(modinv 7 11) ; 8
(modinv 8 12) ; #f 
(modinv 5 12) ; 5
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The algorithm you quoted is Algorithm 9.4.4 from the book Prime Numbers by Richard Crandall and Carl Pomerance. In the text of the book they state that the algorithm works for both prime and composite moduli, but in the errata to their book they correctly state that the algorithm works always for prime moduli and mostly, but not always, for composite moduli. Hence the failure that you found.

Like you, I used Algorithm 9.4.4 and was mystified at some of my results until I discovered the problem.

Here's the modular inverse function that I use now, which works with both prime and composite moduli, as long as its two arguments are coprime to one another. It is essentially the extended Euclidean algorithm that @OscarLopez uses, but with some redundant calculations stripped out. If you like, you can change the function to return #f instead of throwing an error.

(define (inverse x m)
  (let loop ((x x) (b m) (a 0) (u 1))
    (if (zero? x)
        (if (= b 1) (modulo a m)
          (error 'inverse "must be coprime"))
        (let* ((q (quotient b x)))
          (loop (modulo b x) x u (- a (* u q)))))))
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I think this is the Haskell code on that page translated directly into Scheme:

(define (inverse p q)
  (cond ((= p 0) #f)
        ((= p 1) 1)
        (else
          (let ((recurse (inverse (mod q p) p)))
             (and recurse
                  (let ((n (- p recurse)))
                    (div (+ (* n q) 1) p)))))))

It looks like you're trying to convert it from recursive to tail-recursive, which is why things don't match up so well.

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This doesn't even compile, you know... –  Óscar López Oct 27 '12 at 2:52
    
I don't have a Scheme implementation to try it on, so it was untested. But why wouldn't it compile? I'm using functions from R6RS (I don't see modulo or quotient there, it has mod and div). –  Barmar Oct 27 '12 at 2:56
    
It has some basic syntax errors. Besides, I tried first to translate this same algorithm from Haskell to Scheme and it doesn't return the correct results. The algorithm I found and posted in my answer below does work and returns the correct values. –  Óscar López Oct 27 '12 at 2:58
    
If @JohnClements were around, he'd say: "Test cases! Test cases!". * sigh *. Please don't post untested code. –  Óscar López Oct 27 '12 at 3:01
    
I fixed my code. As I said, I don't have a Scheme implementation. I tested this by translating it to Emacs Lisp, debugging i, and translating it back. I think it's correct now. –  Barmar Oct 27 '12 at 4:18

These two functions below can help you as well.

Theory

Here’s how we find the multiplicative inverse d. We want e*d = 1(mod n), which means that ed + nk = 1 for some integer k. So we’ll write a procedure that solves the general equation ax + by = 1, where a and b are given, x and y are variables, and all of these values are integers. We’ll use this procedure to solve ed + nk = 1 for d and k. Then we can throw away k and simply return d. >

(define (ax+by=1 a b)
        (if (= b 0)
            (cons 1 0)
            (let* ((q (quotient a b))
                   (r (remainder a b))
                   (e (ax+by=1 b r))
                   (s (car e))
                   (t (cdr e)))
           (cons t (- s (* q t))))))

This function is a general solution to an equation in form of ax+by=1 where a and b is given.The inverse-mod function simply uses this solution and returns the inverse.

 (define inverse-mod (lambda (a m) 
                  (if (not (= 1 (gcd a m)))
                      (display "**Error** No inverse exists.")
                      (if (> 0(car (ax+by=1 a m)))
                          (+ (car (ax+by=1 a m)) m)
                          (car (ax+by=1 a m))))))

Some test cases are :

(inverse-mod 5 11) ; -> 9 5*9 = 45 = 1 (mod 11)
(inverse-mod 9 11) ; -> 5
(inverse-mod 7 11) ; -> 8 7*8 = 56 = 1 (mod 11)
(inverse-mod 5 12) ; -> 5 5*5 = 25 = 1 (mod 12)
(inverse-mod 8 12) ; -> error no inverse exists
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