DeRhamComputation/elementary_covers/as_cech_class.sage

class as_cech:
    def __init__(self, C, omega, f):
        self.curve = C
        n = C.height
        F = C.base_ring
        variable_names = 'x, y'
        for i in range(n):
            variable_names += ', z' + str(i)
        Rxyz = PolynomialRing(F, n+2, variable_names)
        x, y = Rxyz.gens()[:2]
        z = Rxyz.gens()[2:]
        RxyzQ = FractionField(Rxyz)
        self.omega0 = omega
        self.f = f
        self.omega8 = self.omega0 - self.f.diffn()
        #if self.omega0.form not in Rxyz or self.omega8.valuation() < 0:
        #    raise ValueError('cech cocycle not regular')

    def __repr__(self):
        return "( " + str(self.omega0)+", " + str(self.f) + " )"

    def __add__(self, other):
        C = self.curve
        omega = self.omega0
        f = self.f
        omega1 = other.omega0
        f1 = other.f
        return as_cech(C, omega + omega1, f+f1)

    def __sub__(self, other):
        C = self.curve
        omega = self.omega0
        f = self.f
        omega1 = other.omega0
        f1 = other.f
        return as_cech(C, omega - omega1, f - f1)
    
    def __neg__(self):
        C = self.curve
        omega = self.omega0
        f = self.f
        return as_cech(C, -omega, -f)
    
    def __rmul__(self, constant):
        C = self.curve
        omega = self.omega0
        f = self.f
        return as_cech(C, constant*omega, constant*f)
    
    def reduce(self):
        return as_cech(self.curve, self.omega0.reduce(), self.f.reduce())
    
    def coordinates(self, threshold=10, basis = 0):
        '''Find coordinates of self in the de Rham cohomology basis. Threshold is an argument passed to AS.de_rham_basis().'''
        AS = self.curve
        C = AS.quotient
        m = C.exponent
        r = C.polynomial.degree()
        n = AS.height
        p = AS.characteristic
        RxyzQ, Rxyz, x, y, z = AS.fct_field
        if basis == 0:
            basis = [AS.holomorphic_differentials_basis(), AS.cohomology_of_structure_sheaf_basis(), AS.de_rham_basis(threshold=threshold)]
        holo_diffs = basis[0]
        coh_basis =  basis[1]
        dR = basis[2]
        F = AS.base_ring
        f_products = []
        for f in coh_basis:
            f_products += [[omega.serre_duality_pairing(f) for omega in holo_diffs]]
        product_of_fct_and_omegas = []
        fct = self.f
        product_of_fct_and_omegas = [omega.serre_duality_pairing(fct) for omega in holo_diffs]

        V = (F^(AS.genus())).span_of_basis([vector(a) for a in f_products])
        coh_coordinates = V.coordinates(product_of_fct_and_omegas) #coeficients of self in the basis elts coming from cohomology of OX
        for i in range(AS.genus()):
            self -= coh_coordinates[i]*dR[i+AS.genus()]
        coh_coordinates = AS.genus()*[0] + list(coh_coordinates)
        if self.f.function not in Rxyz:
            #We remove now from f the summands which are obviously regular at infty
            pr = [list(GF(p)) for _ in range(n)]
            S = []
            from itertools import product
            for i in range(0, threshold*r):
                for j in range(0, m):
                    for k in product(*pr):
                        g = (AS.x)^i*prod((AS.z[i1])^(k[i1]) for i1 in range(n))*(AS.y)^j
                        S += [(g, g.expansion_at_infty())]
            S += [(self.f, self.f.expansion_at_infty())]
            fcts = holomorphic_combinations_fcts(S, 0)
            for g in fcts:
                if g.function not in Rxyz:
                    for a in F:
                        if (self.f.function - a*g.function in Rxyz):
                            self.f.function = self.f.function - a*g.function
                            return vector(coh_coordinates)+vector(self.coordinates(threshold=threshold, basis = basis))
        else:
            self.omega0 -= self.f.diffn()
            return vector(coh_coordinates) + vector(list(self.omega0.coordinates(basis=holo_diffs))+AS.genus()*[0])
        
        raise ValueError("Increase threshold.")
        
    def group_action(self, g):
        AS = self.curve
        omega = self.omega0
        f = self.f
        return as_cech(self.curve, omega.group_action(g), f.group_action(g))
    
    def trace(self):
        AS = self.curve
        return as_cech(AS, self.omega0.trace(), self.f.trace())
arbitrary p-gp covers, pt 1 2024-06-10 19:55:49 +02:00			`class as_cech:`
			`def __init__(self, C, omega, f):`
			`self.curve = C`
			`n = C.height`
			`F = C.base_ring`
			`variable_names = 'x, y'`
			`for i in range(n):`
			`variable_names += ', z' + str(i)`
			`Rxyz = PolynomialRing(F, n+2, variable_names)`
			`x, y = Rxyz.gens()[:2]`
			`z = Rxyz.gens()[2:]`
			`RxyzQ = FractionField(Rxyz)`
			`self.omega0 = omega`
			`self.f = f`
			`self.omega8 = self.omega0 - self.f.diffn()`
			`#if self.omega0.form not in Rxyz or self.omega8.valuation() < 0:`
			`# raise ValueError('cech cocycle not regular')`

			`def __repr__(self):`
			`return "( " + str(self.omega0)+", " + str(self.f) + " )"`

			`def __add__(self, other):`
			`C = self.curve`
			`omega = self.omega0`
			`f = self.f`
			`omega1 = other.omega0`
			`f1 = other.f`
			`return as_cech(C, omega + omega1, f+f1)`

			`def __sub__(self, other):`
			`C = self.curve`
			`omega = self.omega0`
			`f = self.f`
			`omega1 = other.omega0`
			`f1 = other.f`
			`return as_cech(C, omega - omega1, f - f1)`

			`def __neg__(self):`
			`C = self.curve`
			`omega = self.omega0`
			`f = self.f`
			`return as_cech(C, -omega, -f)`

			`def __rmul__(self, constant):`
			`C = self.curve`
			`omega = self.omega0`
			`f = self.f`
			`return as_cech(C, constantomega, constantf)`

			`def reduce(self):`
			`return as_cech(self.curve, self.omega0.reduce(), self.f.reduce())`

			`def coordinates(self, threshold=10, basis = 0):`
			`'''Find coordinates of self in the de Rham cohomology basis. Threshold is an argument passed to AS.de_rham_basis().'''`
			`AS = self.curve`
			`C = AS.quotient`
			`m = C.exponent`
			`r = C.polynomial.degree()`
			`n = AS.height`
			`p = AS.characteristic`
			`RxyzQ, Rxyz, x, y, z = AS.fct_field`
			`if basis == 0:`
			`basis = [AS.holomorphic_differentials_basis(), AS.cohomology_of_structure_sheaf_basis(), AS.de_rham_basis(threshold=threshold)]`
			`holo_diffs = basis[0]`
			`coh_basis = basis[1]`
			`dR = basis[2]`
			`F = AS.base_ring`
			`f_products = []`
			`for f in coh_basis:`
			`f_products += [[omega.serre_duality_pairing(f) for omega in holo_diffs]]`
			`product_of_fct_and_omegas = []`
			`fct = self.f`
			`product_of_fct_and_omegas = [omega.serre_duality_pairing(fct) for omega in holo_diffs]`

			`V = (F^(AS.genus())).span_of_basis([vector(a) for a in f_products])`
			`coh_coordinates = V.coordinates(product_of_fct_and_omegas) #coeficients of self in the basis elts coming from cohomology of OX`
			`for i in range(AS.genus()):`
			`self -= coh_coordinates[i]*dR[i+AS.genus()]`
			`coh_coordinates = AS.genus()*[0] + list(coh_coordinates)`
			`if self.f.function not in Rxyz:`
			`#We remove now from f the summands which are obviously regular at infty`
			`pr = [list(GF(p)) for _ in range(n)]`
			`S = []`
			`from itertools import product`
			`for i in range(0, threshold*r):`
			`for j in range(0, m):`
			`for k in product(*pr):`
			`g = (AS.x)^iprod((AS.z[i1])^(k[i1]) for i1 in range(n))(AS.y)^j`
			`S += [(g, g.expansion_at_infty())]`
			`S += [(self.f, self.f.expansion_at_infty())]`
			`fcts = holomorphic_combinations_fcts(S, 0)`
			`for g in fcts:`
			`if g.function not in Rxyz:`
			`for a in F:`
			`if (self.f.function - a*g.function in Rxyz):`
			`self.f.function = self.f.function - a*g.function`
			`return vector(coh_coordinates)+vector(self.coordinates(threshold=threshold, basis = basis))`
			`else:`
			`self.omega0 -= self.f.diffn()`
			`return vector(coh_coordinates) + vector(list(self.omega0.coordinates(basis=holo_diffs))+AS.genus()*[0])`

			`raise ValueError("Increase threshold.")`

			`def group_action(self, g):`
			`AS = self.curve`
			`omega = self.omega0`
			`f = self.f`
			`return as_cech(self.curve, omega.group_action(g), f.group_action(g))`

			`def trace(self):`
			`AS = self.curve`
			`return as_cech(AS, self.omega0.trace(), self.f.trace())`