These 2 functions perform Extended Euclidean Algorithm, and then find the multiplicative inverse. The order seems right, but it's not coming back with what I'm expecting as per this tool from U of Sydney http://magma.maths.usyd.edu.au/calc/ and since this is done in the GF(2) finite field, I think I'm missing some key step that translates from base 10 into this field.

This was tested and worked on base 10, but taking in polynomials with binary coefficients might not be possible here. So my question is what parts of Python am I incorrectly applying to this algorithm, such as // floor, that may not carry from what the function was capable of in base 10 to be able to do this in GF(2).

The tool above can be tested like this:

```
R<x>:=PolynomialRing(GF(2));
p:=x^13+x+1; q:=x^12+x;
g,r,s:=XGCD(p,q);
g eq r*p+s*q;
g,r,s;
```

The functions:

```
def extendedEuclideanGF2(self,a,b): # extended euclidean. a,b are values 10110011... in integer form
inita,initb=a,b; x,prevx=0,1; y,prevy = 1,0
while b != 0:
q = int("{0:b}".format(a//b),2)
a,b = b,int("{0:b}".format(a%b),2);
x,prevx = (int("{0:b}".format(prevx-q*x)), int("{0:b}".format(x,2))); y,prevy=(prevy-q*y, y)
print("Euclidean %d * %d + %d * %d = %d" % (inita,prevx,initb,prevy,a))
return a,prevx,prevy # returns gcd of (a,b), and factors s and t
def modular_inverse(self,a,mod): # a,mod are integer values of 101010111... form
a,mod = prepBinary(a,mod)
bitsa = int("{0:b}".format(a),2); bitsb = int("{0:b}".format(mod),2)
#return bitsa,bitsb,type(bitsa),type(bitsb),a,mod,type(a),type(mod)
gcd,s,t = extendedEuclideanGF2(a,mod); s = int("{0:b}".format(s))
initmi = s%mod; mi = int("{0:b}".format(initmi))
print ("M Inverse %d * %d mod %d = 1"%(a,initmi,mod))
if gcd !=1: return mi,False
return mi # returns modular inverse of a,mod
```

I've been testing with polynomials like this but in binary form of course:

```
p = "x**13 + x**1 + x**0"
q = "x**12 + x**1"
```