Module: sage.schemes.plane_curves.affine_curve
Affine plane curves over a general ring
Author Log:
Class: AffineCurve_finite_field
Functions: rational_points
self, [algorithm=enum]) |
Return sorted list of all rational points on this curve.
Use very naive point enumeration to find all rational points on this curve over a finite field.
sage: A, (x,y) = AffineSpace(2,GF(9,'a')).objgens() sage: C = Curve(x^2 + y^2 - 1) sage: C Affine Curve over Finite Field in a of size 3^2 defined by x0^2 + x1^2 - 1 sage: C.rational_points() [(0, 1), (0, 2), (1, 0), (2, 0), (a + 1, a + 1), (a + 1, 2*a + 2), (2*a + 2, a + 1), (2*a + 2, 2*a + 2)]
Class: AffineCurve_generic
self, A, f) |
Functions: divisor_of_function,
local_coordinates
self, r) |
Return the divisor of a function on a curve.
Input: r is a rational function on X
Output:
sage: F = GF(5) sage: P2 = AffineSpace(2, F, names = 'xy') sage: R = P2.coordinate_ring() sage: x, y = R.gens() sage: f = y^2 - x^9 - x sage: C = Curve(f) sage: K = FractionField(R) sage: r = 1/x sage: C.divisor_of_function(r) # todo: not implemented (broken) [[-1, (0, 0, 1)]] sage: r = 1/x^3 sage: C.divisor_of_function(r) # todo: not implemented (broken) [[-3, (0, 0, 1)]]
self, pt, n) |
Return local coordinates to precision n at the given point.
Input:
sage: F = GF(5) sage: pt = (2,3) sage: R = PolynomialRing(F,2, names = ['x','y']) sage: x,y = R.gens() sage: f = y^2-x^9-x sage: C = Curve(f) sage: C.local_coordinates(pt, 9) [t + 2, -2*t^12 - 2*t^11 + 2*t^9 + t^8 - 2*t^7 - 2*t^6 - 2*t^4 + t^3 - 2*t^2 - 2]
Special Functions: __init__,
_repr_type
Class: AffineCurve_prime_finite_field
Functions: rational_points,
riemann_roch_basis
self, [algorithm=enum]) |
Return sorted list of all rational points on this curve.
Input:
Note: The Brill-Noether package does not always work. When it fails a RuntimeError exception is raised.
sage: x, y = (GF(5)['x,y']).gens() sage: f = y^2 - x^9 - x sage: C = Curve(f); C Affine Curve over Finite Field of size 5 defined by -x^9 + y^2 - x sage: C.rational_points(algorithm='bn') [(0, 0), (2, 2), (2, 3), (3, 1), (3, 4)] sage: C = Curve(x - y + 1) sage: C.rational_points() [(0, 1), (1, 2), (2, 3), (3, 4), (4, 0)]
The following seems to run fine on Linux but *crashes* on OS X intel:
sage: x, y = (GF(17)['x,y']).gens() sage: C = Curve(x^2 + y^5 + x*y - 19) sage: v = C.rational_points(algorithm='bn') # not tested sage: w = C.rational_points(algorithm='enum') # not tested sage: len(v) # not tested 20 sage: v == w # not tested True
self, D) |
Interfaces with Singular's BrillNoether command.
Input:
sage: R = PolynomialRing(GF(5),2,names = ["x","y"]) sage: x, y = R.gens() sage: f = y^2 - x^9 - x sage: C = Curve(f) sage: D = [6,0,0,0,0,0] sage: C.riemann_roch_basis(D) [1, (y^2*z^4 - x*z^5)/x^6, (y^2*z^5 - x*z^6)/x^7, (y^2*z^6 - x*z^7)/x^8]
Class: AffineSpaceCurve_generic
self, A, X) |
Special Functions: __init__,
_repr_type