152 lines
5.0 KiB
Python
152 lines
5.0 KiB
Python
class superelliptic_function:
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'''Class of rational functions on a superelliptic curve C. g = g(x, y) is a polynomial
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defining the function.'''
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def __init__(self, C, g):
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F = C.base_ring
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Rxy.<x, y> = PolynomialRing(F, 2)
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Fxy = FractionField(Rxy)
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f = C.polynomial
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r = f.degree()
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m = C.exponent
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self.curve = C
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g = reduction(C, g)
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self.function = g
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def __eq__(self, other):
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if self.function == other.function:
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return True
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return False
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def __repr__(self):
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return str(self.function)
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def jth_component(self, j):
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g = self.function
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C = self.curve
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F = C.base_ring
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Rx.<x> = PolynomialRing(F)
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Fx.<x> = FractionField(Rx)
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FxRy.<y> = PolynomialRing(Fx)
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g = FxRy(g)
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return coff(g, j)
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def __add__(self, other):
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C = self.curve
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g1 = self.function
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g2 = other.function
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g = reduction(C, g1 + g2)
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return superelliptic_function(C, g)
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def __neg__(self):
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C = self.curve
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g = self.function
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return superelliptic_function(C, -g)
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def __sub__(self, other):
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C = self.curve
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g1 = self.function
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g2 = other.function
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g = reduction(C, g1 - g2)
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return superelliptic_function(C, g)
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def __mul__(self, other):
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C = self.curve
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try:
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g1 = self.function
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g2 = other.function
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g = reduction(C, g1 * g2)
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return superelliptic_function(C, g)
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except:
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g1 = self.function
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g2 = other.form
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g = reduction(C, g1 * g2)
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return superelliptic_form(C, g)
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def __rmul__(self, constant):
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C = self.curve
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g = self.function
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return superelliptic_function(C, constant*g)
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def __truediv__(self, other):
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C = self.curve
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g1 = self.function
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g2 = other.function
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g = reduction(C, g1 / g2)
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return superelliptic_function(C, g)
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def __pow__(self, exp):
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C = self.curve
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g = self.function
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return superelliptic_function(C, g^(exp))
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def diffn(self):
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C = self.curve
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f = C.polynomial
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m = C.exponent
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F = C.base_ring
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g = self.function
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Rxy.<x, y> = PolynomialRing(F, 2)
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Fxy = FractionField(Rxy)
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g = Fxy(g)
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A = g.derivative(x)
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B = g.derivative(y)*f.derivative(x)/(m*y^(m-1))
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return superelliptic_form(C, A+B)
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def coordinates(self, basis = 0, basis_holo = 0, prec=50):
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'''Find coordinates in H1(X, OX) in given basis basis with dual basis basis_holo.'''
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C = self.curve
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if basis == 0:
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basis = C.cohomology_of_structure_sheaf_basis()
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if basis_holo == 0:
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basis_holo = C.holomorphic_differentials_basis()
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g = C.genus()
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coordinates = g*[0]
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for i, omega in enumerate(basis_holo):
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coordinates[i] = -omega.serre_duality_pairing(self, prec=prec)
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return coordinates
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def expansion_at_infty(self, place = 0, prec=20):
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C = self.curve
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fct = self.function
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F = C.base_ring
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Rt.<t> = LaurentSeriesRing(F, default_prec=prec)
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xx = C.x_series[place]
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yy = C.y_series[place]
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return Rt(fct(x = Rt(xx), y = Rt(yy)))
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def expansion(self, pt, prec = 50):
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'''Expansion in the completed ring of the point pt. If pt is an integer, it means the corresponding place at infinity.'''
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if pt in ZZ:
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return self.expansion_at_infty(place=pt, prec=prec)
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x0, y0 = pt[0], pt[1]
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C = self.curve
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f = C.polynomial
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F = C.base_ring
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m = C.exponent
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Rt.<t> = LaurentSeriesRing(F, default_prec=prec)
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Rxy.<x, y> = PolynomialRing(F, 2)
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Fxy = FractionField(Rxy)
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if y0 !=0 and f.derivative()(x0) != 0:
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y_series = f(x = t + x0).nth_root(m)
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return Rt(self.function(x = t + x0, y = y_series))
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if f.derivative()(x0) == 0: # then x - x0 is a uniformizer
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y_series = Rt(f(x = t+x0).nth_root(m))
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return Rt(self.function(x = t + x0, y = y_series))
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if y0 == 0: #then y is a uniformizer
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f1 = f(x = x+x0) - y0
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x_series = new_reverse(f1(x = t), prec = prec)
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x_series = x_series(t = t^m - y0) + x0
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return self.function(x = x_series, y = t)
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def pth_root(self):
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'''Compute p-th root of given function. This uses the following fact: if h = H^p, then C(h*dx/x) = H*dx/x.'''
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C = self.curve
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if self.diffn().form != 0:
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raise ValueError("Function is not a p-th power.")
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Fxy, Rxy, x, y = C.fct_field
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auxilliary_form = superelliptic_form(C, self.function/x)
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auxilliary_form = auxilliary_form.cartier()
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auxilliary_form = C.x * auxilliary_form
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auxilliary_form = auxilliary_form.form
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return superelliptic_function(C, auxilliary_form) |