# algorithms for modular inverses

i have read section about The Extended Euclidean Algorithm & Modular Inverses,which states that it not only computes `GCD(n,m)` but also a and b such that `a*n+b*b=1;` algorithm is described by by this way:

1. Write down n, m, and the two-vectors (1,0) and (0,1)
2. Divide the larger of the two numbers by the smaller - call this quotient q
3. Subtract q times the smaller from the larger (ie reduce the larger modulo the smaller)

(i have question here if we denote by q n/m,then `n-q*m is` not equal to 0?because q=n/m;(assume that n>m),so why it is necessary such kind of operation? then 4 step

4.Subtract q times the vector corresponding to the smaller from the vector corresponding to the larger 5.Repeat steps 2 through 4 until the result is zero 6.Publish the preceding result as gcd(n,m)

so my question for this problem also is how can i implement this steps in code?please help me,i dont know how start and from which point could i start to solve such problem,for clarify result ,it should look like this An example of this algorithm is the following computation of 30^(-1)(mod 53);

``````53           30           (1,0)                        (0,1)
53-1*30=23   30           (1,0)-1*(0,1)=(1,-1)         (0,1)
23           30-1*23=7    (1,-1)                       (0,1)-1*(1,-1)=(-1,2)
23-3*7=2      7           (1,-1)-3*(-1,2)=(4,-7)       (-1,2)
2             7-3*2=1     (4,-7)                      (-1,2)-3*(4,7)=(-13,23)
2-2*1=0       1           (4,-7)-2*(-13,23)=(30,-53)   (-13,23)
``````

From this we see that gcd(30,53)=1 and, rearranging terms, we see that 1=-13*53+23*30, so we conclude that 30^(-1)=23(mod 53).

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What? I'm very confused –  Grammin Sep 30 '11 at 16:47
for more information please see this site userpages.umbc.edu/~rcampbel/NumbThy/Class/BasicNumbThy.html and see this section The Extended Euclidean Algorithm & Modular Inverses –  dato datuashvili Sep 30 '11 at 16:53
Show us the code you have so far. Regarding step 3: q is the integer part of n/m, so the remainder n-q*m can be nonzero. –  Jim Lewis Sep 30 '11 at 16:54
i am also confused @Grammin i dont know where store result when for instance make vectors operation –  dato datuashvili Sep 30 '11 at 16:58

The division is supposed to be integer division with truncation. The standard EA for `gcd(a, b)` with `a <= b` goes like this:

`````` b =  a * q0 + r0
a = r0 * q1 + r1
r0 = r1 * q2 + r2
...
r[N+1] = 0
``````

Now `rN` is the desired GCD. Then you back-substitute:

``````r[N-1] = r[N] * q[N+1]

r[N-2] = r[N-1] * q[N] + r[N]
= (r[N] * q[N+1]) * q[N] + r[N]
= r[N] * (q[N+1] * q[N] + 1)

r[N-3] = r[N-2] * q[N-1] + r[N-1]
= ... <substitute> ...
``````

Until you finally reach `rN = m * a + n * b`. The algorithm you describe keeps track of the backtracking data right away, so it's a bit more efficient.

If `rN == gcd(a, b) == 1`, then you have indeed found the multiplicative inverse of `a` modulo `b`, namely `m`: `(a * m) % b == 1`.

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