Exemple #1
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    def _to_relaxed_matrix_bp(self, graph):
        # convert graph to a topological sorting of the vertices
        nodes = nx.topological_sort(graph.graph)
        # the accept vertex must be last
        a = nodes.index(('acc', graph.num))
        b = nodes.index(('rej', graph.num))
        if a < b:
            nodes[b], nodes[a] = nodes[a], nodes[b]
        # the source vertex must be first
        src = nodes.index(('src', graph.num))
        nodes[0], nodes[src] = nodes[src], nodes[0]

        mapping = dict(zip(nodes, range(self.size)))
        g = nx.relabel_nodes(graph.graph, mapping)
        # convert graph to relaxed matrix BP
        self.bp = []
        G = MatrixSpace(GF(2), self.size)
        for layer in xrange(self.nlayers):
            zero = copy(G.one())
            one = copy(G.one())
            for edge in g.edges_iter():
                e = g[edge[0]][edge[1]]
                assert e['label'] in (0, 1)
                if g.node[edge[0]]['layer'] == layer:
                    if e['label'] == 0:
                        zero[edge[0], edge[1]] = 1
                    else:
                        one[edge[0], edge[1]] = 1
            self.bp.append(Layer(graph.inp(layer), zero, one))
        self.zero = G.one()
Exemple #2
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    def _to_relaxed_matrix_bp(self, graph):
        # convert graph to a topological sorting of the vertices
        nodes = nx.topological_sort(graph.graph)
        # the accept vertex must be last
        a = nodes.index(('acc', graph.num))
        b = nodes.index(('rej', graph.num))
        if a < b:
            nodes[b], nodes[a] = nodes[a], nodes[b]
        # the source vertex must be first
        src = nodes.index(('src', graph.num))
        nodes[0], nodes[src] = nodes[src], nodes[0]

        mapping = dict(zip(nodes, range(self.size)))
        g = nx.relabel_nodes(graph.graph, mapping)
        # convert graph to relaxed matrix BP
        self.bp = []
        G = MatrixSpace(GF(2), self.size)
        for layer in xrange(self.nlayers):
            zero = copy(G.one())
            one = copy(G.one())
            for edge in g.edges_iter():
                e = g[edge[0]][edge[1]]
                assert e['label'] in (0, 1)
                if g.node[edge[0]]['layer'] == layer:
                    if e['label'] == 0:
                        zero[edge[0], edge[1]] = 1
                    else:
                        one[edge[0], edge[1]] = 1
            self.bp.append(Layer(graph.inp(layer), zero, one))
        self.zero = G.one()
Exemple #3
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 def randomize(self, prime):
     assert not self.randomized
     prev = None
     for i in xrange(0, len(self.bp)):
         d_i_minus_one = self.bp[i].zero.nrows()
         d_i = self.bp[i].zero.ncols()
         MSZp = MatrixSpace(ZZ.residue_field(ZZ.ideal(prime)), d_i_minus_one, d_i)
         MSZp_square = MatrixSpace(ZZ.residue_field(ZZ.ideal(prime)), d_i, d_i)
         if i != 0:
             MSZp = MatrixSpace(ZZ.residue_field(ZZ.ideal(prime)), d_i_minus_one, d_i)
             self.bp[i] = self.bp[i].group(MSZp, prime).mult_left(prev.adjoint())
         if i != len(self.bp) - 1:
             cur = MSZp_square.random_element()
             self.bp[i] = self.bp[i].group(MSZp, prime).mult_right(cur)
             prev = cur
     # compute S * B_0
     d_0 = self.bp[0].zero.nrows()
     d_1 = self.bp[0].zero.ncols()
     S = matrix.identity(d_0)
     for i in xrange(d_0):
         S[i, i] = random.randint(0, prime - 1)
     MSZp = MatrixSpace(ZZ.residue_field(ZZ.ideal(prime)), d_0, d_1)
     self.bp[0] = self.bp[0].group(MSZp, prime).mult_left(S)
     # compute B_ell * T
     r = self.bp[-1].zero.nrows()
     c = self.bp[-1].zero.ncols()
     T = matrix.identity(c)
     for i in xrange(c):
         T[i, i] = random.randint(0, prime - 1)
     MSZp = MatrixSpace(ZZ.residue_field(ZZ.ideal(prime)), r, c)
     self.bp[-1] = self.bp[-1].group(MSZp, prime).mult_right(T)
     self.randomized = True
Exemple #4
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 def integral_cuspidal_subspace(self):
     """
     In certatain cases this might return the integral structure of the cuspidal subspace.
     This code is mainly a way to compute the integral structe faster than sage does now. 
     It returns None if it cannot find the integral subspace. 
     """
     if self.verbose: tm = cputime(); mem = get_memory_usage(); print("Int struct start")
     #This code is the same as the firs part of self.M.integral_structure
     G = set([i for i, _ in self.M._mod2term])
     G = list(G)
     G.sort()
     #if there is a two term relation between two manin symbols we only need one of the two
     #so that's why we only use elements from G instead of all manin symbols.
     if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "G")
     B = self.M._manin_gens_to_basis.matrix_from_rows(list(G)).sparse_matrix()
     if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "B")
     #The collums of B now span self.M.integral_structure as ZZ-module
     B, d = B._clear_denom()
     if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "Clear denom")
     if d == 1:
         #for explanation see d == 2
         assert len(set([B.nonzero_positions_in_row(i)[0] for i in range(B.nrows()) if len(B.nonzero_positions_in_row(i)) == 1 and B[i, B.nonzero_positions_in_row(i)[0]] == 1])) == B.ncols(), "B doesn't contain the Identity"
         if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "Check Id")
         ZZbasis = MatrixSpace(QQ, B.ncols(), sparse=True)(1)
         if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "ZZbasis")
     elif d == 2:
         #in this case the matrix B will contain 2*Id as a minor this allows us to compute the hermite normal form of B in a very efficient way. This will give us the integral basis ZZbasis.
         #if it turns out to be nessecarry this can be generalized to the case d%4==2 if we don't mind to only get the right structure localized at 2
         assert len(set([B.nonzero_positions_in_row(i)[0] for i in range(B.nrows()) if len(B.nonzero_positions_in_row(i)) == 1 and B[i, B.nonzero_positions_in_row(i)[0]] == 2])) == B.ncols(), "B doesn't contain 2*Identity"    
         if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "Check 2*Id")
         E = matrix_modp(B,sparse=True)
         if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "matmodp")
         E = E.echelon_form()
         if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "echelon")
         ZZbasis = MatrixSpace(QQ, B.ncols(), sparse=True)(1)
         for (pivot_row, pivot_col) in zip(E.pivot_rows(), E.pivots()):
             for j in E.nonzero_positions_in_row(pivot_row):
                 ZZbasis[pivot_col, j] = QQ(1) / 2 
         if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "ZZbasis")
     else:
         return None
     #now we compute the integral kernel of the boundary map with respect to the integral basis. This will give us the integral cuspidal submodule.                 
     boundary_matrix = self.M.boundary_map().matrix()
     if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "Boundary matrix")
     ZZboundary_matrix=(ZZbasis*boundary_matrix).change_ring(ZZ)
     if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "ZZBoundary matrix")
     left_kernel_matrix=ZZboundary_matrix.transpose().dense_matrix()._right_kernel_matrix(algorithm='pari')
     if type(left_kernel_matrix)==tuple:
         left_kernel_matrix=left_kernel_matrix[1]
     if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "kernel matrix")
     ZZcuspidal_basis=left_kernel_matrix*ZZbasis
     if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "ZZkernel matrix")
     assert ZZcuspidal_basis.change_ring(QQ).echelon_form()==self.S.basis_matrix() , "the calculated integral basis does not span the right QQ vector space" # a little sanity check. This shows that the colums of ZZcuspidal_basis really span the right QQ vectorspace
     if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "check")
     #finally create the sub-module, we delibarately do this as a QQ vector space with custom basis, because this is faster then dooing the calculations over ZZ since sage will then use a slow hermite normal form algorithm.
     ambient_module=VectorSpace(QQ,ZZcuspidal_basis.ncols())
     int_struct = ambient_module.submodule_with_basis(ZZcuspidal_basis.rows())
     if self.verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "finnished")
     return int_struct
Exemple #5
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def is_quotient(M, sym, rank):
    symbol = GenusSymbol_global_ring(MatrixSpace(ZZ, rank, rank).one())
    symbol._local_symbols = [
        Genus_Symbol_p_adic_ring(p, syms) for p, syms in sym.iteritems()
    ]
    s = get_symbol_string(symbol)
    print s
    N = FiniteQuadraticModule(s)
    t = N.order() / M.order()
    if not Integer(t).is_square():
        return False
    else:
        t = sqrt(t)
    for p in Integer(N.order()).prime_factors():
        if not N.signature(p) == M.signature(p):
            return False
    # if not N.signature() == M.signature():
    #    return False
    for G in N.subgroups():
        if G.order() == t and G.is_isotropic():
            Q = G.quotient()
            if Q.is_isomorphic(M):
                print Q
                return N
            else:
                del Q
    del N
    return False
Exemple #6
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    def semidirect_rep_from_twisted_cocycle(self, cocycle):
        """
        Given a representation rho to GL(R, n) and a rho-twisted
        1-cocycle, construct the representation to GL(R, n + 1)
        corresponding to the semidirect product.

        Note: Since we prefer to stick to left-actions only, unlike [HLK]
        this is the semidirect produce associated to the left action of
        GL(R, n) on V = R^n.  That is, pairs (v, A) with v in V and A in
        GL(R, n) where (v, A) * (w, B) = (v + A*w, A*B)::

           sage: G = Manifold('K12a169').fundamental_group()
           sage: A = matrix(GF(5), [[0, 4], [1, 4]])
           sage: rho = cyclic_rep(G, A)
           sage: cocycle = vector(GF(5), (0, 0, 1, 0))
           sage: rho_til = rho.semidirect_rep_from_twisted_cocycle(cocycle)
           sage: rho_til('abAB')
           [1 0 4]
           [0 1 1]
           [0 0 1]
        """
        gens, rels, rho = self.generators, self.relators, self
        n = rho.dim
        assert len(cocycle) == len(gens) * n
        new_mats = []
        for i, g in enumerate(gens):
            v = matrix([cocycle[i * n:(i + 1) * n]]).transpose()
            zeros = matrix(n * [0])
            one = matrix([[1]])
            A = block_matrix([[rho(g), v], [zeros, one]])
            new_mats.append(A)

        target = MatrixSpace(rho.base_ring, n + 1)
        return MatrixRepresentation(gens, rels, target, new_mats)
Exemple #7
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    def _compute_IJ(self, p, e):
        global B, F
        if p.number_field() != B.base():
            raise ValueError(
                "p must be a prime ideal in the base field of the quaternion algebra"
            )
        if not p.is_prime():
            raise ValueError("p must be prime")

        if p.number_field() != B.base():
            raise ValueError(
                "p must be a prime ideal in the base field of the quaternion algebra"
            )
        if not p.is_prime():
            raise ValueError("p must be prime")
        if F is not p.number_field():
            raise ValueError("p must be a prime of {0}".format(F))

        R = residue_ring(p**e)
        if isinstance(R, ResidueRing_base):
            k = R.ring()
        else:
            k = R

        from sage.all import MatrixSpace
        M = MatrixSpace(k, 2)

        i2, j2 = B.invariants()
        i2 = R(i2)
        j2 = R(j2)

        if k.characteristic() == 2:
            raise NotImplementedError

        # Find I -- just write it down
        I = M([0, i2, 1, 0])
        # Find J -- I figured this out by just writing out the general case
        # and seeing what the parameters have to satisfy
        i2inv = k(1) / i2
        a = None
        for b in R.list():
            if not b: continue
            c = j2 + i2inv * b * b
            if c.is_square():
                a = -c.sqrt()
                break
        if a is None:
            # do a fallback search; needed in char 3 sometimes.
            for J in M:
                K = I * J
                if J * J == j2 and K == -J * I:
                    return I, J, K

        J = M([a, b, (j2 - a * a) / b, -a])
        K = I * J
        assert K == -J * I, "bug in that I,J don't skew commute"
        return I, J, R
Exemple #8
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def ambient_integral_structure_matrix(M,verbose=False):
    """
    In certatain cases (weight two any level) this might return the integral structure of a
    an ambient modular symbol space. I wrote this because for high level this is very slow
    in sage because there is no good sparse hermite normal form code in sage for huge matrices.
    """
    if verbose: tm = cputime(); mem = get_memory_usage(); print("Int struct start")
    #This code is the same as the firs part of M.integral_structure
    G = set([i for i, _ in M._mod2term])
    G = list(G)
    G.sort()
    #if there is a two term relation between two manin symbols we only need one of the two
    #so that's why we only use elements from G instead of all manin symbols.
    if verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "G")
    B = M._manin_gens_to_basis.matrix_from_rows(list(G)).sparse_matrix()
    if verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "B")
    #The collums of B now span M.integral_structure as ZZ-module
    B, d = B._clear_denom()
    if verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "Clear denom")
    if d == 1:
        #for explanation see d == 2
        assert len(set([B.nonzero_positions_in_row(i)[0] for i in range(B.nrows()) if len(B.nonzero_positions_in_row(i)) == 1 and B[i, B.nonzero_positions_in_row(i)[0]] == 1])) == B.ncols(), "B doesn't contain the Identity"
        if verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "Check Id")
        ZZbasis = MatrixSpace(QQ, B.ncols(), sparse=True)(1)
        if verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "ZZbasis")
    elif d == 2:
        #in this case the matrix B will contain 2*Id as a minor this allows us to compute the hermite normal form of B in a very efficient way. This will give us the integral basis ZZbasis.
        #if it turns out to be nessecarry this can be generalized to the case d%4==2 if we don't mind to only get the right structure localized at 2
        assert len(set([B.nonzero_positions_in_row(i)[0] for i in range(B.nrows()) if len(B.nonzero_positions_in_row(i)) == 1 and B[i, B.nonzero_positions_in_row(i)[0]] == 2])) == B.ncols(), "B doesn't contain 2*Identity"    
        if verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "Check 2*Id")
        E = matrix_modp(B,sparse=True)
        if verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "matmodp")
        E = E.echelon_form()
        if verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "echelon")
        ZZbasis = MatrixSpace(QQ, B.ncols(), sparse=True)(1)
        for (pivot_row, pivot_col) in zip(E.pivot_rows(), E.pivots()):
            for j in E.nonzero_positions_in_row(pivot_row):
                ZZbasis[pivot_col, j] = QQ(1) / 2 
        if verbose: print("time and mem", cputime(tm), get_memory_usage(mem), "ZZbasis")
    else:
        raise NotImplementedError
    return ZZbasis
Exemple #9
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def induced_rep_from_twisted_cocycle(p, rho, chi, cocycle):
    """
    The main metabelian representation from Section 7 of [HKL] for the
    group of a knot complement, where p is the degree of the branched
    cover, rho is an irreducible cyclic representation acting on the
    F_q vector space V, chi is a homomorpism V -> F_q, and cocycle
    describes the semidirect product extension.

    We differ from [HKL] in that all actions are on the left, meaning
    that this representation is defined in terms of the convention for the
    semidirect product discussed in::

      MatrixRepresentation.semidirect_rep_from_twisted_cocycle

    Here is an example::

       sage: G = Manifold('K12n132').fundamental_group()
       sage: A = matrix(GF(5), [[0, 4], [1, 4]])
       sage: rho = cyclic_rep(G, A)
       sage: cocycle = (0, 0, 0, 1, 1, 2)
       sage: chi = lambda v: v[0] + 4*v[1]
       sage: rho_ind = induced_rep_from_twisted_cocycle(3, rho, chi, cocycle)
       sage: rho_ind('c').list()
       [0, 0, (-z^3 - z^2 - z - 1), z^2*t^-1, 0, 0, 0, (-z^3 - z^2 - z - 1)*t^-1, 0]
    """
    q = rho.base_ring.order()
    n = rho.dim
    K = CyclotomicField(q, 'z')
    z = K.gen()
    A = rho.A
    R = LaurentPolynomialRing(K, 't')
    t = R.gen()
    MatSp = MatrixSpace(R, p)
    gens = rho.generators
    images = dict()
    for s, g in enumerate(gens):
        v = vector(cocycle[s * n:(s + 1) * n])
        e = rho.epsilon(g)[0]
        U = MatSp(0)
        for j in range(0, p):
            k, l = (e + j).quo_rem(p)
            U[l, j] = t**k * z**chi(A**(-l) * v)
        images[g] = U

        e, v = -e, -A**(-e) * v
        V = MatSp(0)
        for j in range(0, p):
            k, l = (e + j).quo_rem(p)
            V[l, j] = t**k * z**chi(A**(-l) * v)
        images[g.swapcase()] = V

    alpha = MatrixRepresentation(gens, rho.relators, MatSp, images)
    alpha.epsilon = rho.epsilon
    return alpha
Exemple #10
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def test_eigenvalues(prec=100, nmax=10, dimmax=10):
    r"""
    Test the eigenvalue computations for some random matrices.
    """
    F = MPComplexField(prec)
    dim = ZZ.random_element(2, dimmax)
    M = MatrixSpace(F, dim)
    for n in range(nmax):
        A, U, l = random_matrix_eigenvalues(F, dim)
        ev = A.eigenvalues()
        ev.sort()
        l.sort()
        test = max([abs(ev[j] - l[j]) for j in range(len(ev))])
        assert test < A.eps() * 100
Exemple #11
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    def _test_matrix_smith(self, **options):
        r"""
        Test that :meth:`_matrix_smith_form` works correctly.

        EXAMPLES::

            sage: ZpCA(5, 15)._test_matrix_smith()

        """
        tester = self._tester(**options)
        tester.assertEqual(self.residue_field().characteristic(),
                           self.residue_characteristic())

        from itertools import chain
        from sage.all import MatrixSpace
        from .precision_error import PrecisionError
        matrices = chain(*[
            MatrixSpace(self, n, m).some_elements() for n in (1, 3, 7)
            for m in (1, 4, 7)
        ])
        for M in tester.some_elements(matrices):
            bases = [self]
            if self is not self.integer_ring():
                bases.append(self.integer_ring())
            for base in bases:
                try:
                    S, U, V = M.smith_form(integral=base)
                except PrecisionError:
                    continue

                if self.is_exact() or self._prec_type() not in [
                        'fixed-mod', 'floating-point'
                ]:
                    tester.assertEqual(U * M * V, S)

                tester.assertEqual(U.nrows(), U.ncols())
                tester.assertEqual(U.base_ring(), base)

                tester.assertEqual(V.nrows(), V.ncols())
                tester.assertEqual(V.base_ring(), base)

                for d in S.diagonal():
                    if not d.is_zero():
                        tester.assertTrue(d.unit_part().is_one())

                for (d, dd) in zip(S.diagonal(), S.diagonal()[1:]):
                    tester.assertTrue(d.divides(dd))
Exemple #12
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def random_matrix_eigenvalues(F, n):
    r"""
    Give a random matrix together with its eigenvalues.
    """
    l = list()
    M = MatrixSpace(F, n)
    U = Matrix(F, n)
    D = Matrix(F, n)
    for i in xrange(n):
        x = F.random_element()
        l.append(x)
        D[i, i] = x
    # now we need a unitary matrix:
    # make a random choice of vectors and use Gram-Schmidt to orthogonolize
    U = random_unitary_matrix(F, n)
    UT = U.transpose().conjugate()
    A = U * D * UT
    l.sort(cmp=my_abscmp)
    return A, U, l
    def __pow__(self, n, _=None):
        r"""
        Return the vector space of dimension ``n`` over this field.

        EXAMPLES::

            sage: from pyeantic import RealEmbeddedNumberField
            sage: K = NumberField(x**2 - 2, 'a', embedding=sqrt(AA(2)))
            sage: K = RealEmbeddedNumberField(K)
            sage: K^3
            Vector space of dimension 3 over Real Embedded Number Field in a with defining polynomial x^2 - 2 with a = 1.414213562373095?

        """
        if isinstance(n, tuple):
            m, n = n
            from sage.all import MatrixSpace
            return MatrixSpace(self, m, n)
        else:
            from sage.all import VectorSpace
            return VectorSpace(self, n)
Exemple #14
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    def randomize(self, prime):
        assert not self.randomized
        MSZp = MatrixSpace(ZZ.residue_field(ZZ.ideal(prime)), self.size)

        def random_matrix():
            while True:
                m = MSZp.random_element()
                if not m.is_singular() and m.rank() == self.size:
                    return m, m.inverse()

        m0, m0i = random_matrix()
        self.bp[0] = self.bp[0].group(MSZp, prime).mult_left(m0)
        for i in xrange(1, len(self.bp)):
            mi, mii = random_matrix()
            self.bp[i - 1] = self.bp[i - 1].group(MSZp, prime).mult_right(mii)
            self.bp[i] = self.bp[i].group(MSZp, prime).mult_left(mi)
        self.bp[-1] = self.bp[-1].group(MSZp, prime).mult_right(m0i)
        VSZp = VectorSpace(ZZ.residue_field(ZZ.ideal(prime)), self.size)
        self.s = copy(VSZp.zero())
        self.s[0] = 1
        self.t = copy(VSZp.zero())
        self.t[len(self.t) - 1] = 1
        self.m0, self.m0i = m0, m0i
        self.randomized = True
Exemple #15
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 def randomize(self, prime):
     assert not self.randomized
     prev = None
     for i in xrange(0, len(self.bp)):
         d_i_minus_one = self.bp[i].zero.nrows()
         d_i = self.bp[i].zero.ncols()
         MSZp = MatrixSpace(ZZ.residue_field(ZZ.ideal(prime)),
                            d_i_minus_one, d_i)
         MSZp_square = MatrixSpace(ZZ.residue_field(ZZ.ideal(prime)), d_i,
                                   d_i)
         if i != 0:
             MSZp = MatrixSpace(ZZ.residue_field(ZZ.ideal(prime)),
                                d_i_minus_one, d_i)
             self.bp[i] = self.bp[i].group(MSZp,
                                           prime).mult_left(prev.adjoint())
         if i != len(self.bp) - 1:
             cur = MSZp_square.random_element()
             self.bp[i] = self.bp[i].group(MSZp, prime).mult_right(cur)
             prev = cur
     # compute S * B_0
     d_0 = self.bp[0].zero.nrows()
     d_1 = self.bp[0].zero.ncols()
     S = matrix.identity(d_0)
     for i in xrange(d_0):
         S[i, i] = random.randint(0, prime - 1)
     MSZp = MatrixSpace(ZZ.residue_field(ZZ.ideal(prime)), d_0, d_1)
     self.bp[0] = self.bp[0].group(MSZp, prime).mult_left(S)
     # compute B_ell * T
     r = self.bp[-1].zero.nrows()
     c = self.bp[-1].zero.ncols()
     T = matrix.identity(c)
     for i in xrange(c):
         T[i, i] = random.randint(0, prime - 1)
     MSZp = MatrixSpace(ZZ.residue_field(ZZ.ideal(prime)), r, c)
     self.bp[-1] = self.bp[-1].group(MSZp, prime).mult_right(T)
     self.randomized = True
Exemple #16
0
"""
Tools for use in Sage.
"""

import os, sys, re, string, tempfile
from ..sage_helper import _within_sage, sage_method

if _within_sage:
    import sage
    from sage.all import (ZZ, vector, matrix, block_matrix, gcd, prod, det,
                          MatrixSpace, AbelianGroup, GroupAlgebra, SageObject,
                          PolynomialRing, LaurentPolynomialRing)

    from .polished_reps import polished_holonomy, MatrixRepresentation
    Id2 = MatrixSpace(ZZ, 2)(1)
else:
    SageObject = object
    ZZ, Id2 = None, None


def search_for_low_rank_triangulation(M, trys=100, target_lower_bound=0):
    rank_lower_bound = max(M.homology().rank(), target_lower_bound)

    rank_upper_bound = M.fundamental_group().num_generators()
    N = M.copy()
    curr_best_tri = N.copy()
    for i in range(trys):
        if rank_upper_bound == rank_lower_bound:
            break
        N.randomize()
        new_rank = N.fundamental_group().num_generators()
Exemple #17
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def vector_to_double_char(v):
    assert len(v) == 2
    return CHARSET[v[0]] + CHARSET[v[1]]


def encrypt(msg, K):
    assert all(c in CHARSET for c in msg)
    assert len(msg) % 2 == 0

    A, v = K
    ciphertext = ""
    for i in range(0, len(msg), 2):
        tmp = A * double_char_to_vector(msg[i:i + 2]) + v
        ciphertext += vector_to_double_char(tmp)

    return ciphertext


if __name__ == '__main__':
    from secret import flag
    assert flag.startswith('kmactf')
    A = MatrixSpace(Fp, 2, 2).random_element()
    v = VectorSpace(Fp, 2).random_element()
    assert A.determinant() != 0
    print('ciphertext =', repr(encrypt(flag, (A, v))))

    # Output:
    # ciphertext = 'u_rm3eefa}_7det1znb{sce{qo0h7yf0b}sktse8xtr6'
def solve(vectors, goal):
  M = MatrixSpace(GF(2), len(vectors), len(vectors[0]))
  V = VectorSpace(GF(2), len(goal))
  A = M(vectors)
  b = V(goal)
  return A.solve_left(b)
Exemple #19
0
    def rho(self,M,silent=0,numeric=0,prec=-1):
        r""" The Weil representation acting on SL(2,Z).

        INPUT::

        -``M`` -- element of SL2Z
        - ''numeric'' -- set to 1 to return a Matrix_complex_dense with prec=prec instead of exact
        - ''prec'' -- precision
        EXAMPLES::
        
            sage: WR=WeilRepDiscriminantForm(1,dual=False)
            sage: S,T=SL2Z.gens()
            sage: WR.rho(S)
            [
            [-zeta8^3 -zeta8^3]
            [-zeta8^3  zeta8^3], sqrt(1/2)
            ]
            sage: WR.rho(T)
            [
            [       1        0]
            [       0 -zeta8^2], 1
            ]
            sage: A=SL2Z([-1,1,-4,3]); WR.rho(A)
            [
            [zeta8^2       0]
            [      0       1], 1
            ]
            sage: A=SL2Z([41,77,33,62]); WR.rho(A)
            [
            [-zeta8^3  zeta8^3]
            [   zeta8    zeta8], sqrt(1/2)
            ]

        """
        N=self._N; D=2*N; D2=2*D
        if numeric==0:
            K=CyclotomicField (lcm(4*self._N,8))
            z=K(CyclotomicField(4*self._N).gen())
            rho=matrix(K,D)
        else:
            CF = MPComplexField(prec)
            RF = CF.base()
            MS = MatrixSpace(CF,int(D),int(D))
            rho = Matrix_complex_dense(MS)
            #arg = RF(2)*RF.pi()/RF(4*self._N)
            z = CF(0,RF(2)*RF.pi()/RF(4*self._N)).exp()
        [a,b,c,d]=M
        fak=1; sig=1
        if c<0:
            # need to use the reflection 
            # r(-A)=r(Z)r(A)sigma(Z,A)  where sigma(Z,A)=-1 if c>0
            sig=-1
            if numeric==0:
                fz=CyclotomicField(4).gen() # = i
            else:
                fz=CF(0,1)
            # the factor is rho(Z) sigma(Z,-A)
            #if(c < 0 or (c==0 and d>0)):
            #    fak=-fz
            #else:
            #sig=1
            #fz=1
            fak=fz
            a=-a; b=-b; c=-c; d=-d;
            A=SL2Z([a,b,c,d])
            if numeric==0:
                chi=self.xi(A)            
            else:
                chi=CF(self.xi(A).complex_embedding(prec))
            if(silent>0):
                print("fz={0}".format(fz))
                print("chi={0}".format(chi))
        elif c == 0: # then we use the simple formula
            if d < 0:
                sig=-1
                if numeric == 0:
                    fz=CyclotomicField(4).gen()
                else:
                    fz=CF(0,1)
                fak=fz
                a=-a; b=-b; c=-c; d=-d;
            else:
                fak=1
            for alpha in range(D):
                arg=(b*alpha*alpha ) % D2
                if(sig==-1):
                    malpha = (D - alpha) % D
                    rho[malpha,alpha]=fak*z**arg
                else:
                    #print "D2=",D2
                    #print "b=",b
                    #print "arg=",arg
                    rho[alpha,alpha]=z**arg
            return [rho,1]
        else:
            if numeric==0:
                chi=self.xi(M)            
            else:
                chi=CF(self.xi(M).complex_embedding(prec))
        Nc=gcd(Integer(D),Integer(c))
        #chi=chi*sqrt(CF(Nc)/CF(D))
        if(valuation(Integer(c),2)==valuation(Integer(D),2)):
            xc=Integer(N)
        else:
            xc=0
        if silent>0:
            print("c={0}".format(c))
            print("xc={0}".format(xc))
            print("chi={0}".format(chi))
        for alpha in range(D):
            al=QQ(alpha)/QQ(D)
            for beta in range(D):
                be=QQ(beta)/QQ(D)
                c_div=False
                if(xc==0):
                    alpha_minus_dbeta=(alpha-d*beta) % D
                else:
                    alpha_minus_dbeta=(alpha-d*beta-xc) % D
                if silent > 0: # and alpha==7 and beta == 7):
                    print("alpha,beta={0},{1}".format(alpha,beta))
                    print("c,d={0},{1}".format(c,d))
                    print("alpha-d*beta={0}".format(alpha_minus_dbeta))
                invers=0
                for r in range(D):
                    if (r*c - alpha_minus_dbeta) % D ==0:
                        c_div=True
                        invers=r
                        break
                if c_div and silent > 0:
                    print("invers={0}".format(invers))
                    print(" inverse(alpha-d*beta) mod c={0}".format(invers))
                elif(silent>0):
                    print(" no inverse!")
                if(c_div):
                    y=invers
                    if xc==0:
                        argu=a*c*y**2+b*d*beta**2+2*b*c*y*beta
                    else:
                        argu=a*c*y**2+2*xc*(a*y+b*beta)+b*d*beta**2+2*b*c*y*beta
                    argu = argu % D2
                    tmp1=z**argu  # exp(2*pi*I*argu)
                    if silent>0:# and alpha==7 and beta==7):
                        print("a,b,c,d={0},{1},{2},{3}".format(a,b,c,d))
                        print("xc={0}".format(xc))
                        print("argu={0}".format(argu))
                        print("exp(...)={0}".format(tmp1))
                        print("chi={0}".format(chi))
                        print("sig={0}".format(sig))
                    if sig == -1:
                        minus_alpha = (D - alpha) % D
                        rho[minus_alpha,beta]=tmp1*chi
                    else:
                        rho[alpha,beta]=tmp1*chi
        #print "fak=",fak
        if numeric==0:            
            return [fak*rho,sqrt(QQ(Nc)/QQ(D))]
        else:
            return [CF(fak)*rho,RF(sqrt(QQ(Nc)/QQ(D)))]
Exemple #20
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 def __init__(self, phi, alpha, N):
     self.base_ring = phi.range()
     self.image_ring = MatrixSpace(self.base_ring, N)
     self.phi, self.alpha, self.N = phi, alpha, N
Exemple #21
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def modp_splitting(p):
    """
    INPUT:
        
        - p -- ideal of the number field K = B.base() with ring O of integers.
        
    OUTPUT:
        
        - matrices I, J in M_2(O/p) such that i |--> I and j |--> J defines 
          an algebra morphism, i.e., I^2=a, J^2=b, I*J=-J*I.

    EXAMPLES::    

        sage: from psage.modform.hilbert.sqrt5.sqrt5 import F, B, modp_splitting
        sage: c = F.factor(31)[0][0]
        sage: modp_splitting(c)
        (
        [ 0 30]  [18  4]
        [ 1  0], [ 4 13]
        )
        sage: c = F.factor(37)[0][0]; c
        Fractional ideal (37)
        sage: I, J = modp_splitting(c); I, J
        (
        [ 0 36]  [23*abar + 21  36*abar + 8]
        [ 1  0], [ 36*abar + 8 14*abar + 16]
        )
        sage: I^2
        [36  0]
        [ 0 36]
        sage: J^2
        [36  0]
        [ 0 36]
        sage: I*J == -J*I
        True

    AUTHOR: William Stein
    """
    global B, F

    # Inspired by the code in the function
    # modp_splitting_data in algebras/quatalg/quaternion_algebra.py
    if p.number_field() != B.base():
        raise ValueError, "p must be a prime ideal in the base field of the quaternion algebra"
    if not p.is_prime():
        raise ValueError, "p must be prime"

    if F is not p.number_field():
        raise ValueError, "p must be a prime of %s" % F

    k = p.residue_field()

    from sage.all import MatrixSpace
    M = MatrixSpace(k, 2)
    i2, j2 = B.invariants()
    i2 = k(i2)
    j2 = k(j2)
    if k.characteristic() == 2:
        if i2 == 0 or j2 == 0:
            raise NotImplementedError
        return M([0, 1, 1, 0]), M([1, 1, 0, 1])
    # Find I -- just write it down
    I = M([0, i2, 1, 0])
    # Find J -- I figured this out by just writing out the general case
    # and seeing what the parameters have to satisfy
    i2inv = 1 / i2
    a = None
    for b in list(k):
        if not b: continue
        c = j2 + i2inv * b * b
        if c.is_square():
            a = -c.sqrt()
            break
    if a is None:
        # do a fallback search; needed in char 3 sometimes.
        for J in M:
            K = I * J
            if J * J == j2 and K == -J * I:
                return I, J, K

    J = M([a, b, (j2 - a * a) / b, -a])
    K = I * J
    assert K == -J * I, "bug in that I,J don't skew commute"
    return I, J
Exemple #22
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3-manifold to very high precision.
"""
import os, sys, re, string, tempfile
from itertools import product, chain
from functools import reduce
from ..sage_helper import _within_sage
from ..pari import pari

from .fundamental_polyhedron import *

if _within_sage:
    import sage
    from sage.all import RealField, ComplexField, gcd, prod, powerset
    from sage.all import MatrixSpace, matrix, vector, ZZ
    Object = sage.structure.sage_object.SageObject
    identity = lambda A: MatrixSpace(A.base_ring(), A.nrows())(1)
    abelian_group_elt = lambda v: vector(ZZ, v)
else:
    Object = object
    from .utilities import Matrix2x2 as matrix, powerset
    from ..number import Number

    def identity(A):
        return matrix(A.base_ring(), 1.0, 0.0, 0.0, 1.0)

    def prod(L, initial=None):
        if initial:
            return reduce(lambda x, y: x * y, L, initial)
        elif L:
            return reduce(lambda x, y: x * y, L)
        else: