+ fmt = "Euclidean Jordan algebra of degree {} over {}"
+ return fmt.format(self.degree(), self.base_ring())
+
+ def rank(self):
+ """
+ Return the rank of this EJA.
+ """
+ if self._rank is None:
+ raise ValueError("no rank specified at genesis")
+ else:
+ return self._rank
+
+
+ class Element(FiniteDimensionalAlgebraElement):
+ """
+ An element of a Euclidean Jordan algebra.
+ """
+
+ def __pow__(self, n):
+ """
+ Return ``self`` raised to the power ``n``.
+
+ Jordan algebras are always power-associative; see for
+ example Faraut and Koranyi, Proposition II.1.2 (ii).
+
+ .. WARNING:
+
+ We have to override this because our superclass uses row vectors
+ instead of column vectors! We, on the other hand, assume column
+ vectors everywhere.
+
+ EXAMPLES:
+
+ sage: set_random_seed()
+ sage: x = random_eja().random_element()
+ sage: x.matrix()*x.vector() == (x**2).vector()
+ True
+
+ """
+ A = self.parent()
+ if n == 0:
+ return A.one()
+ elif n == 1:
+ return self
+ else:
+ return A.element_class(A, (self.matrix()**(n-1))*self.vector())
+
+
+ def characteristic_polynomial(self):
+ """
+ Return my characteristic polynomial (if I'm a regular
+ element).
+
+ Eventually this should be implemented in terms of the parent
+ algebra's characteristic polynomial that works for ALL
+ elements.
+ """
+ if self.is_regular():
+ return self.minimal_polynomial()
+ else:
+ raise NotImplementedError('irregular element')
+
+
+ def det(self):
+ """
+ Return my determinant, the product of my eigenvalues.
+
+ EXAMPLES::
+
+ sage: J = eja_ln(2)
+ sage: e0,e1 = J.gens()
+ sage: x = e0 + e1
+ sage: x.det()
+ 0
+ sage: J = eja_ln(3)
+ sage: e0,e1,e2 = J.gens()
+ sage: x = e0 + e1 + e2
+ sage: x.det()
+ -1
+
+ """
+ cs = self.characteristic_polynomial().coefficients(sparse=False)
+ r = len(cs) - 1
+ if r >= 0:
+ return cs[0] * (-1)**r
+ else:
+ raise ValueError('charpoly had no coefficients')
+
+
+ def is_nilpotent(self):
+ """
+ Return whether or not some power of this element is zero.
+
+ The superclass method won't work unless we're in an
+ associative algebra, and we aren't. However, we generate
+ an assocoative subalgebra and we're nilpotent there if and
+ only if we're nilpotent here (probably).
+
+ TESTS:
+
+ The identity element is never nilpotent::
+
+ sage: set_random_seed()
+ sage: random_eja().one().is_nilpotent()
+ False
+
+ The additive identity is always nilpotent::
+
+ sage: set_random_seed()
+ sage: random_eja().zero().is_nilpotent()
+ True
+
+ """
+ # The element we're going to call "is_nilpotent()" on.
+ # Either myself, interpreted as an element of a finite-
+ # dimensional algebra, or an element of an associative
+ # subalgebra.
+ elt = None
+
+ if self.parent().is_associative():
+ elt = FiniteDimensionalAlgebraElement(self.parent(), self)
+ else:
+ V = self.span_of_powers()
+ assoc_subalg = self.subalgebra_generated_by()
+ # Mis-design warning: the basis used for span_of_powers()
+ # and subalgebra_generated_by() must be the same, and in
+ # the same order!
+ elt = assoc_subalg(V.coordinates(self.vector()))
+
+ # Recursive call, but should work since elt lives in an
+ # associative algebra.
+ return elt.is_nilpotent()
+
+
+ def is_regular(self):
+ """
+ Return whether or not this is a regular element.
+
+ EXAMPLES:
+
+ The identity element always has degree one, but any element
+ linearly-independent from it is regular::
+
+ sage: J = eja_ln(5)
+ sage: J.one().is_regular()
+ False
+ sage: e0, e1, e2, e3, e4 = J.gens() # e0 is the identity
+ sage: for x in J.gens():
+ ....: (J.one() + x).is_regular()
+ False
+ True
+ True
+ True
+ True
+
+ """
+ return self.degree() == self.parent().rank()
+
+
+ def degree(self):
+ """
+ Compute the degree of this element the straightforward way
+ according to the definition; by appending powers to a list
+ and figuring out its dimension (that is, whether or not
+ they're linearly dependent).
+
+ EXAMPLES::
+
+ sage: J = eja_ln(4)
+ sage: J.one().degree()
+ 1
+ sage: e0,e1,e2,e3 = J.gens()
+ sage: (e0 - e1).degree()
+ 2
+
+ In the spin factor algebra (of rank two), all elements that
+ aren't multiples of the identity are regular::
+
+ sage: set_random_seed()
+ sage: n = ZZ.random_element(1,10).abs()
+ sage: J = eja_ln(n)
+ sage: x = J.random_element()
+ sage: x == x.coefficient(0)*J.one() or x.degree() == 2
+ True
+
+ """
+ return self.span_of_powers().dimension()
+
+
+ def matrix(self):
+ """
+ Return the matrix that represents left- (or right-)
+ multiplication by this element in the parent algebra.
+
+ We have to override this because the superclass method
+ returns a matrix that acts on row vectors (that is, on
+ the right).
+ """
+ fda_elt = FiniteDimensionalAlgebraElement(self.parent(), self)
+ return fda_elt.matrix().transpose()
+
+
+ def minimal_polynomial(self):
+ """
+ EXAMPLES::
+
+ sage: set_random_seed()
+ sage: x = random_eja().random_element()
+ sage: x.degree() == x.minimal_polynomial().degree()
+ True
+
+ ::
+
+ sage: set_random_seed()
+ sage: x = random_eja().random_element()
+ sage: x.degree() == x.minimal_polynomial().degree()
+ True
+
+ The minimal polynomial and the characteristic polynomial coincide
+ and are known (see Alizadeh, Example 11.11) for all elements of
+ the spin factor algebra that aren't scalar multiples of the
+ identity::
+
+ sage: set_random_seed()
+ sage: n = ZZ.random_element(2,10).abs()
+ sage: J = eja_ln(n)
+ sage: y = J.random_element()
+ sage: while y == y.coefficient(0)*J.one():
+ ....: y = J.random_element()
+ sage: y0 = y.vector()[0]
+ sage: y_bar = y.vector()[1:]
+ sage: actual = y.minimal_polynomial()
+ sage: x = SR.symbol('x', domain='real')
+ sage: expected = x^2 - 2*y0*x + (y0^2 - norm(y_bar)^2)
+ sage: bool(actual == expected)
+ True
+
+ """
+ # The element we're going to call "minimal_polynomial()" on.
+ # Either myself, interpreted as an element of a finite-
+ # dimensional algebra, or an element of an associative
+ # subalgebra.
+ elt = None
+
+ if self.parent().is_associative():
+ elt = FiniteDimensionalAlgebraElement(self.parent(), self)
+ else:
+ V = self.span_of_powers()
+ assoc_subalg = self.subalgebra_generated_by()
+ # Mis-design warning: the basis used for span_of_powers()
+ # and subalgebra_generated_by() must be the same, and in
+ # the same order!
+ elt = assoc_subalg(V.coordinates(self.vector()))
+
+ # Recursive call, but should work since elt lives in an
+ # associative algebra.
+ return elt.minimal_polynomial()
+
+
+ def quadratic_representation(self):
+ """
+ Return the quadratic representation of this element.
+
+ EXAMPLES:
+
+ The explicit form in the spin factor algebra is given by
+ Alizadeh's Example 11.12::
+
+ sage: n = ZZ.random_element(1,10).abs()
+ sage: J = eja_ln(n)
+ sage: x = J.random_element()
+ sage: x_vec = x.vector()
+ sage: x0 = x_vec[0]
+ sage: x_bar = x_vec[1:]
+ sage: A = matrix(QQ, 1, [x_vec.inner_product(x_vec)])
+ sage: B = 2*x0*x_bar.row()
+ sage: C = 2*x0*x_bar.column()
+ sage: D = identity_matrix(QQ, n-1)
+ sage: D = (x0^2 - x_bar.inner_product(x_bar))*D
+ sage: D = D + 2*x_bar.tensor_product(x_bar)
+ sage: Q = block_matrix(2,2,[A,B,C,D])
+ sage: Q == x.quadratic_representation()
+ True
+
+ """
+ return 2*(self.matrix()**2) - (self**2).matrix()
+
+
+ def span_of_powers(self):
+ """
+ Return the vector space spanned by successive powers of
+ this element.
+ """
+ # The dimension of the subalgebra can't be greater than
+ # the big algebra, so just put everything into a list
+ # and let span() get rid of the excess.
+ V = self.vector().parent()
+ return V.span( (self**d).vector() for d in xrange(V.dimension()) )
+
+
+ def subalgebra_generated_by(self):
+ """
+ Return the associative subalgebra of the parent EJA generated
+ by this element.
+
+ TESTS::
+
+ sage: set_random_seed()
+ sage: x = random_eja().random_element()
+ sage: x.subalgebra_generated_by().is_associative()
+ True
+
+ Squaring in the subalgebra should be the same thing as
+ squaring in the superalgebra::
+
+ sage: set_random_seed()
+ sage: x = random_eja().random_element()
+ sage: u = x.subalgebra_generated_by().random_element()
+ sage: u.matrix()*u.vector() == (u**2).vector()
+ True
+
+ """
+ # First get the subspace spanned by the powers of myself...
+ V = self.span_of_powers()
+ F = self.base_ring()
+
+ # Now figure out the entries of the right-multiplication
+ # matrix for the successive basis elements b0, b1,... of
+ # that subspace.
+ mats = []
+ for b_right in V.basis():
+ eja_b_right = self.parent()(b_right)
+ b_right_rows = []
+ # The first row of the right-multiplication matrix by
+ # b1 is what we get if we apply that matrix to b1. The
+ # second row of the right multiplication matrix by b1
+ # is what we get when we apply that matrix to b2...
+ #
+ # IMPORTANT: this assumes that all vectors are COLUMN
+ # vectors, unlike our superclass (which uses row vectors).
+ for b_left in V.basis():
+ eja_b_left = self.parent()(b_left)
+ # Multiply in the original EJA, but then get the
+ # coordinates from the subalgebra in terms of its
+ # basis.
+ this_row = V.coordinates((eja_b_left*eja_b_right).vector())
+ b_right_rows.append(this_row)
+ b_right_matrix = matrix(F, b_right_rows)
+ mats.append(b_right_matrix)
+
+ # It's an algebra of polynomials in one element, and EJAs
+ # are power-associative.
+ #
+ # TODO: choose generator names intelligently.
+ return FiniteDimensionalEuclideanJordanAlgebra(F, mats, assume_associative=True, names='f')