def mynumerator(x): if parent(x) == R: return x return numerator(x) class fastfrac: def __init__(self,top,bot=1): if parent(top) == ZZ or parent(top) == R: self.top = R(top) self.bot = R(bot) elif top.__class__ == fastfrac: self.top = top.top self.bot = top.bot * bot else: self.top = R(numerator(top)) self.bot = R(denominator(top)) * bot def reduce(self): return fastfrac(self.top / self.bot) def sreduce(self): return fastfrac(I.reduce(self.top),I.reduce(self.bot)) def iszero(self): return self.top in I and not (self.bot in I) def isdoublingzero(self): return self.top in J and not (self.bot in J) def __add__(self,other): if parent(other) == ZZ: return fastfrac(self.top + self.bot * other,self.bot) if other.__class__ == fastfrac: return fastfrac(self.top * other.bot + self.bot * other.top,self.bot * other.bot) return NotImplemented def __sub__(self,other): if parent(other) == ZZ: return fastfrac(self.top - self.bot * other,self.bot) if other.__class__ == fastfrac: return fastfrac(self.top * other.bot - self.bot * other.top,self.bot * other.bot) return NotImplemented def __neg__(self): return fastfrac(-self.top,self.bot) def __mul__(self,other): if parent(other) == ZZ: return fastfrac(self.top * other,self.bot) if other.__class__ == fastfrac: return fastfrac(self.top * other.top,self.bot * other.bot) return NotImplemented def __rmul__(self,other): return self.__mul__(other) def __div__(self,other): if parent(other) == ZZ: return fastfrac(self.top,self.bot * other) if other.__class__ == fastfrac: return fastfrac(self.top * other.bot,self.bot * other.top) return NotImplemented def __pow__(self,other): if parent(other) == ZZ: return fastfrac(self.top ^ other,self.bot ^ other) return NotImplemented def isidentity(x): return x.iszero() def isdoublingidentity(x): return x.isdoublingzero() R. = PolynomialRing(GF(2),12,order='invlex') I = R.ideal([ mynumerator((uy1^2+ux1*uy1)-(ux1^3+ua2*ux1^2+ua6)) , mynumerator((ux1)-(uX1/uZ1)) , mynumerator((uy1)-(uY1/uZ1)) , mynumerator((uy2^2+ux2*uy2)-(ux2^3+ua2*ux2^2+ua6)) , mynumerator((ux2)-(uX2/uZ2)) , mynumerator((uy2)-(uY2/uZ2)) ]) J = I + R.ideal([0 , uX1-uX2 , uY1-uY2 , uZ1-uZ2 ]) ua2 = fastfrac(ua2) ua6 = fastfrac(ua6) ux2 = fastfrac(ux2) uy2 = fastfrac(uy2) ux1 = fastfrac(ux1) uy1 = fastfrac(uy1) uX1 = fastfrac(uX1) uY1 = fastfrac(uY1) uZ1 = fastfrac(uZ1) uX2 = fastfrac(uX2) uY2 = fastfrac(uY2) uZ2 = fastfrac(uZ2) uA = ((uY1*uZ2+uZ1*uY2)) uB = ((uX1*uZ2+uZ1*uX2)) uC = ((uB^2)) uD = ((uZ1*uZ2)) uE = (((uA^2+uA*uB+ua2*uC)*uD+uB*uC)) uX3 = ((uB*uE)) uY3 = ((uC*(uA*uX1+uY1*uB)*uZ2+(uA+uB)*uE)) uZ3 = ((uB^3*uD)) ux3 = ((((uy1+uy2)/(ux1+ux2))^2+((uy1+uy2)/(ux1+ux2))+ux1+ux2+ua2)).reduce() uy3 = ((((uy1+uy2)/(ux1+ux2))^3+(ux2+ua2+fastfrac(1))*((uy1+uy2)/(ux1+ux2))+ux1+ux2+ua2+uy1)).reduce() print isidentity((uy3^2+ux3*uy3)-(ux3^3+ua2*ux3^2+ua6)) print isidentity((ux3)-(uX3/uZ3)) print isidentity((uy3)-(uY3/uZ3)) unified = True uX4 = uX3 uY4 = uY3 uZ4 = uZ3 ux4 = (((ux1+uy1/ux1)^2+(ux1+uy1/ux1)+ua2)).reduce() uy4 = (((ux1+uy1/ux1)^3+(ux1+ua2+fastfrac(1))*(ux1+uy1/ux1)+ua2+uy1)).reduce() if unified: unified = isdoublingidentity((uy4^2+ux4*uy4)-(ux4^3+ua2*ux4^2+ua6)) if unified: unified = isdoublingidentity((ux4)-(uX4/uZ4)) if unified: unified = isdoublingidentity((uy4)-(uY4/uZ4)) if unified: print "Unified"