def _latex_element_(self, x):
r"""
Finds the LaTeX representation of this expression.
EXAMPLES::
sage: f(A, t, omega, psi) = A*cos(omega*t - psi)
sage: f._latex_()
'\\left( A, t, \\omega, \\psi \\right) \\ {\\mapsto} \\ A \\cos\\left(\\omega t - \\psi\\right)'
sage: f(mu) = mu^3
sage: f._latex_()
'\\mu \\ {\\mapsto}\\ \\mu^{3}'
"""
from sage.misc.latex import latex
args = self.args()
args = [latex(arg) for arg in args]
latex_x = SymbolicRing._latex_element_(self, x)
if len(args) == 1:
return r"%s \ {\mapsto}\ %s" % (args[0], latex_x)
else:
vars = ", ".join(args)
# the weird TeX is to workaround an apparent JsMath bug
return r"\left( %s \right) \ {\mapsto} \ %s" % (vars, latex_x)
def __init__(self, arguments):
"""
EXAMPLES:
We verify that coercion works in the case where ``x`` is not an
instance of SymbolicExpression, but its parent is still the
SymbolicRing::
sage: f(x) = 1
sage: f*e
x |--> e
TESTS::
sage: TestSuite(f.parent()).run(skip=['_test_divides'])
"""
self._arguments = arguments
SymbolicRing.__init__(self, SR)
self._populate_coercion_lists_(coerce_list=[SR])
self.symbols = SR.symbols # Use the same list of symbols as SR
def __init__(self, arguments):
"""
EXAMPLES:
We verify that coercion works in the case where ``x`` is not an
instance of SymbolicExpression, but its parent is still the
SymbolicRing::
sage: f(x) = 1
sage: f*e
x |--> e
TESTS::
sage: TestSuite(f.parent()).run(skip=['_test_divides'])
"""
self._arguments = arguments
SymbolicRing.__init__(self, SR)
self._populate_coercion_lists_(coerce_list=[SR])
self.symbols = SR.symbols # Use the same list of symbols as SR
def _element_constructor_(self, x):
"""
TESTS::
sage: f(x) = x+1; g(y) = y+1
sage: f.parent()(g)
x |--> y + 1
sage: g.parent()(f)
y |--> x + 1
sage: f(x) = x+2*y; g(y) = y+3*x
sage: f.parent()(g)
x |--> 3*x + y
sage: g.parent()(f)
y |--> x + 2*y
"""
return SymbolicRing._element_constructor_(self, x)
def _element_constructor_(self, x):
"""
TESTS::
sage: f(x) = x+1; g(y) = y+1
sage: f.parent()(g)
x |--> y + 1
sage: g.parent()(f)
y |--> x + 1
sage: f(x) = x+2*y; g(y) = y+3*x
sage: f.parent()(g)
x |--> 3*x + y
sage: g.parent()(f)
y |--> x + 2*y
"""
return SymbolicRing._element_constructor_(self, x)
def _coerce_map_from_(self, R):
"""
EXAMPLES::
sage: f(x,y) = x^2 + y
sage: g(x,y,z) = x + y + z
sage: f.parent().has_coerce_map_from(g.parent())
False
sage: g.parent().has_coerce_map_from(f.parent())
True
"""
if is_CallableSymbolicExpressionRing(R):
args = self.arguments()
if all(a in args for a in R.arguments()):
return True
else:
return False
return SymbolicRing._coerce_map_from_(self, R)
def _coerce_map_from_(self, R):
"""
EXAMPLES::
sage: f(x,y) = x^2 + y
sage: g(x,y,z) = x + y + z
sage: f.parent().has_coerce_map_from(g.parent())
False
sage: g.parent().has_coerce_map_from(f.parent())
True
"""
if is_CallableSymbolicExpressionRing(R):
args = self.arguments()
if all(a in args for a in R.arguments()):
return True
else:
return False
return SymbolicRing._coerce_map_from_(self, R)
def _repr_element_(self, x):
"""
Returns the string representation of the Expression ``x``.
EXAMPLES::
sage: f(y,x) = x + y
sage: f
(y, x) |--> x + y
sage: f.parent()
Callable function ring with arguments (y, x)
"""
args = self.arguments()
repr_x = SymbolicRing._repr_element_(self, x)
if len(args) == 1:
return "%s |--> %s" % (args[0], repr_x)
else:
args = ", ".join(map(str, args))
return "(%s) |--> %s" % (args, repr_x)
def _repr_element_(self, x):
"""
Returns the string representation of the Expression ``x``.
EXAMPLES::
sage: f(y,x) = x + y
sage: f
(y, x) |--> x + y
sage: f.parent()
Callable function ring with arguments (y, x)
"""
args = self.arguments()
repr_x = SymbolicRing._repr_element_(self, x)
if len(args) == 1:
return "%s |--> %s" % (args[0], repr_x)
else:
args = ", ".join(map(str, args))
return "(%s) |--> %s" % (args, repr_x)
def _latex_element_(self, x):
r"""
Finds the LaTeX representation of this expression.
EXAMPLES::
sage: f(A, t, omega, psi) = A*cos(omega*t - psi)
sage: f._latex_()
'\\left( A, t, \\omega, \\psi \\right) \\ {\\mapsto} \\ A \\cos\\left(\\omega t - \\psi\\right)'
sage: f(mu) = mu^3
sage: f._latex_()
'\\mu \\ {\\mapsto}\\ \\mu^{3}'
"""
from sage.misc.latex import latex
args = self.args()
args = [latex(arg) for arg in args]
latex_x = SymbolicRing._latex_element_(self, x)
if len(args) == 1:
return r"%s \ {\mapsto}\ %s" % (args[0], latex_x)
else:
vars = ", ".join(args)
return r"\left( %s \right) \ {\mapsto} \ %s" % (vars, latex_x)
def linear_transformation(arg0, arg1=None, arg2=None, side='left'):
r"""
Create a linear transformation from a variety of possible inputs.
FORMATS:
In the following, ``D`` and ``C`` are vector spaces over
the same field that are the domain and codomain
(respectively) of the linear transformation.
``side`` is a keyword that is either 'left' or 'right'.
When a matrix is used to specify a linear transformation,
as in the first two call formats below, you may specify
if the function is given by matrix multiplication with
the vector on the left, or the vector on the right.
The default is 'left'. Internally representations are
always carried as the 'left' version, and the default
text representation is this version. However, the matrix
representation may be obtained as either version, no matter
how it is created.
- ``linear_transformation(A, side='left')``
Where ``A`` is a matrix. The domain and codomain are inferred
from the dimension of the matrix and the base ring of the matrix.
The base ring must be a field, or have its fraction field implemented
in Sage.
- ``linear_transformation(D, C, A, side='left')``
``A`` is a matrix that behaves as above. However, now the domain
and codomain are given explicitly. The matrix is checked for
compatibility with the domain and codomain. Additionally, the
domain and codomain may be supplied with alternate ("user") bases
and the matrix is interpreted as being a representation relative
to those bases.
- ``linear_transformation(D, C, f)``
``f`` is any function that can be applied to the basis elements of the
domain and that produces elements of the codomain. The linear
transformation returned is the unique linear transformation that
extends this mapping on the basis elements. ``f`` may come from a
function defined by a Python ``def`` statement, or may be defined as a
``lambda`` function.
Alternatively, ``f`` may be specified by a callable symbolic function,
see the examples below for a demonstration.
- ``linear_transformation(D, C, images)``
``images`` is a list, or tuple, of codomain elements, equal in number
to the size of the basis of the domain. Each basis element of the domain
is mapped to the corresponding element of the ``images`` list, and the
linear transformation returned is the unique linear transfromation that
extends this mapping.
OUTPUT:
A linear transformation described by the input. This is a
"vector space morphism", an object of the class
:class:`sage.modules.vector_space_morphism`.
EXAMPLES:
We can define a linear transformation with just a matrix, understood to
act on a vector placed on one side or the other. The field for the
vector spaces used as domain and codomain is obtained from the base
ring of the matrix, possibly promoting to a fraction field. ::
sage: A = matrix(ZZ, [[1, -1, 4], [2, 0, 5]])
sage: phi = linear_transformation(A)
sage: phi
Vector space morphism represented by the matrix:
[ 1 -1 4]
[ 2 0 5]
Domain: Vector space of dimension 2 over Rational Field
Codomain: Vector space of dimension 3 over Rational Field
sage: phi([1/2, 5])
(21/2, -1/2, 27)
sage: B = matrix(Integers(7), [[1, 2, 1], [3, 5, 6]])
sage: rho = linear_transformation(B, side='right')
sage: rho
Vector space morphism represented by the matrix:
[1 3]
[2 5]
[1 6]
Domain: Vector space of dimension 3 over Ring of integers modulo 7
Codomain: Vector space of dimension 2 over Ring of integers modulo 7
sage: rho([2, 4, 6])
(2, 6)
We can define a linear transformation with a matrix, while explicitly
giving the domain and codomain. Matrix entries will be coerced into the
common field of scalars for the vector spaces. ::
sage: D = QQ^3
sage: C = QQ^2
sage: A = matrix([[1, 7], [2, -1], [0, 5]])
sage: A.parent()
Full MatrixSpace of 3 by 2 dense matrices over Integer Ring
sage: zeta = linear_transformation(D, C, A)
sage: zeta.matrix().parent()
Full MatrixSpace of 3 by 2 dense matrices over Rational Field
sage: zeta
Vector space morphism represented by the matrix:
[ 1 7]
[ 2 -1]
[ 0 5]
Domain: Vector space of dimension 3 over Rational Field
Codomain: Vector space of dimension 2 over Rational Field
Matrix representations are relative to the bases for the domain
and codomain. ::
sage: u = vector(QQ, [1, -1])
sage: v = vector(QQ, [2, 3])
sage: D = (QQ^2).subspace_with_basis([u, v])
sage: x = vector(QQ, [2, 1])
sage: y = vector(QQ, [-1, 4])
sage: C = (QQ^2).subspace_with_basis([x, y])
sage: A = matrix(QQ, [[2, 5], [3, 7]])
sage: psi = linear_transformation(D, C, A)
sage: psi
Vector space morphism represented by the matrix:
[2 5]
[3 7]
Domain: Vector space of degree 2 and dimension 2 over Rational Field
User basis matrix:
[ 1 -1]
[ 2 3]
Codomain: Vector space of degree 2 and dimension 2 over Rational Field
User basis matrix:
[ 2 1]
[-1 4]
sage: psi(u) == 2*x + 5*y
True
sage: psi(v) == 3*x + 7*y
True
Functions that act on the domain may be used to compute images of
the domain's basis elements, and this mapping can be extended to
a unique linear transformation. The function may be a Python
function (via ``def`` or ``lambda``) or a Sage symbolic function. ::
sage: def g(x):
... return vector(QQ, [2*x[0]+x[2], 5*x[1]])
...
sage: phi = linear_transformation(QQ^3, QQ^2, g)
sage: phi
Vector space morphism represented by the matrix:
[2 0]
[0 5]
[1 0]
Domain: Vector space of dimension 3 over Rational Field
Codomain: Vector space of dimension 2 over Rational Field
sage: f = lambda x: vector(QQ, [2*x[0]+x[2], 5*x[1]])
sage: rho = linear_transformation(QQ^3, QQ^2, f)
sage: rho
Vector space morphism represented by the matrix:
[2 0]
[0 5]
[1 0]
Domain: Vector space of dimension 3 over Rational Field
Codomain: Vector space of dimension 2 over Rational Field
sage: x, y, z = var('x y z')
sage: h(x, y, z) = [2*x + z, 5*y]
sage: zeta = linear_transformation(QQ^3, QQ^2, h)
sage: zeta
Vector space morphism represented by the matrix:
[2 0]
[0 5]
[1 0]
Domain: Vector space of dimension 3 over Rational Field
Codomain: Vector space of dimension 2 over Rational Field
sage: phi == rho
True
sage: rho == zeta
True
We create a linear transformation relative to non-standard bases,
and capture its representation relative to standard bases. With this, we
can build functions that create the same linear transformation relative
to the nonstandard bases. ::
sage: u = vector(QQ, [1, -1])
sage: v = vector(QQ, [2, 3])
sage: D = (QQ^2).subspace_with_basis([u, v])
sage: x = vector(QQ, [2, 1])
sage: y = vector(QQ, [-1, 4])
sage: C = (QQ^2).subspace_with_basis([x, y])
sage: A = matrix(QQ, [[2, 5], [3, 7]])
sage: psi = linear_transformation(D, C, A)
sage: rho = psi.restrict_codomain(QQ^2).restrict_domain(QQ^2)
sage: rho.matrix()
[ -4/5 97/5]
[ 1/5 -13/5]
sage: f = lambda x: vector(QQ, [(-4/5)*x[0] + (1/5)*x[1], (97/5)*x[0] + (-13/5)*x[1]])
sage: psi = linear_transformation(D, C, f)
sage: psi.matrix()
[2 5]
[3 7]
sage: s, t = var('s t')
sage: h(s, t) = [(-4/5)*s + (1/5)*t, (97/5)*s + (-13/5)*t]
sage: zeta = linear_transformation(D, C, h)
sage: zeta.matrix()
[2 5]
[3 7]
Finally, we can give an explicit list of images for the basis
elements of the domain. ::
sage: x = polygen(QQ)
sage: F.<a> = NumberField(x^3+x+1)
sage: u = vector(F, [1, a, a^2])
sage: v = vector(F, [a, a^2, 2])
sage: w = u + v
sage: D = F^3
sage: C = F^3
sage: rho = linear_transformation(D, C, [u, v, w])
sage: rho.matrix()
[ 1 a a^2]
[ a a^2 2]
[ a + 1 a^2 + a a^2 + 2]
sage: C = (F^3).subspace_with_basis([u, v])
sage: D = (F^3).subspace_with_basis([u, v])
sage: psi = linear_transformation(C, D, [u+v, u-v])
sage: psi.matrix()
[ 1 1]
[ 1 -1]
TESTS:
We test some bad inputs. First, the wrong things in the wrong places. ::
sage: linear_transformation('junk')
Traceback (most recent call last):
...
TypeError: first argument must be a matrix or a vector space, not junk
sage: linear_transformation(QQ^2, QQ^3, 'stuff')
Traceback (most recent call last):
...
TypeError: third argument must be a matrix, function, or list of images, not stuff
sage: linear_transformation(QQ^2, 'garbage')
Traceback (most recent call last):
...
TypeError: if first argument is a vector space, then second argument must be a vector space, not garbage
sage: linear_transformation(QQ^2, Integers(7)^2)
Traceback (most recent call last):
...
TypeError: vector spaces must have the same field of scalars, not Rational Field and Ring of integers modulo 7
Matrices must be over a field (or a ring that can be promoted to a field),
and of the right size. ::
sage: linear_transformation(matrix(Integers(6), [[2, 3],[4, 5]]))
Traceback (most recent call last):
...
TypeError: matrix must have entries from a field, or a ring with a fraction field, not Ring of integers modulo 6
sage: A = matrix(QQ, 3, 4, range(12))
sage: linear_transformation(QQ^4, QQ^4, A)
Traceback (most recent call last):
...
TypeError: domain dimension is incompatible with matrix size
sage: linear_transformation(QQ^3, QQ^3, A, side='right')
Traceback (most recent call last):
...
TypeError: domain dimension is incompatible with matrix size
sage: linear_transformation(QQ^3, QQ^3, A)
Traceback (most recent call last):
...
TypeError: codomain dimension is incompatible with matrix size
sage: linear_transformation(QQ^4, QQ^4, A, side='right')
Traceback (most recent call last):
...
TypeError: codomain dimension is incompatible with matrix size
Lists of images can be of the wrong number, or not really
elements of the codomain. ::
sage: linear_transformation(QQ^3, QQ^2, [vector(QQ, [1,2])])
Traceback (most recent call last):
...
ValueError: number of images should equal the size of the domain's basis (=3), not 1
sage: C = (QQ^2).subspace_with_basis([vector(QQ, [1,1])])
sage: linear_transformation(QQ^1, C, [vector(QQ, [1,2])])
Traceback (most recent call last):
...
ArithmeticError: some proposed image is not in the codomain, because
element (= [1, 2]) is not in free module
Functions may not apply properly to domain elements,
or return values outside the codomain. ::
sage: f = lambda x: vector(QQ, [x[0], x[4]])
sage: linear_transformation(QQ^3, QQ^2, f)
Traceback (most recent call last):
...
ValueError: function cannot be applied properly to some basis element because
index out of range
sage: f = lambda x: vector(QQ, [x[0], x[1]])
sage: C = (QQ^2).span([vector(QQ, [1, 1])])
sage: linear_transformation(QQ^2, C, f)
Traceback (most recent call last):
...
ArithmeticError: some image of the function is not in the codomain, because
element (= [1, 0]) is not in free module
A Sage symbolic function can come in a variety of forms that are
not representative of a linear transformation. ::
sage: x, y = var('x, y')
sage: f(x, y) = [y, x, y]
sage: linear_transformation(QQ^3, QQ^3, f)
Traceback (most recent call last):
...
ValueError: symbolic function has the wrong number of inputs for domain
sage: linear_transformation(QQ^2, QQ^2, f)
Traceback (most recent call last):
...
ValueError: symbolic function has the wrong number of outputs for codomain
sage: x, y = var('x y')
sage: f(x, y) = [y, x*y]
sage: linear_transformation(QQ^2, QQ^2, f)
Traceback (most recent call last):
...
ValueError: symbolic function must be linear in all the inputs:
unable to convert y to a rational
sage: x, y = var('x y')
sage: f(x, y) = [x, 2*y]
sage: C = (QQ^2).span([vector(QQ, [1, 1])])
sage: linear_transformation(QQ^2, C, f)
Traceback (most recent call last):
...
ArithmeticError: some image of the function is not in the codomain, because
element (= [1, 0]) is not in free module
"""
from sage.matrix.constructor import matrix
from sage.modules.module import is_VectorSpace
from sage.modules.free_module import VectorSpace
from sage.categories.homset import Hom
from sage.symbolic.ring import SymbolicRing
from sage.modules.vector_callable_symbolic_dense import Vector_callable_symbolic_dense
from inspect import isfunction
if not side in ['left', 'right']:
raise ValueError(
"side must be 'left' or 'right', not {0}".format(side))
if not (is_Matrix(arg0) or is_VectorSpace(arg0)):
raise TypeError(
'first argument must be a matrix or a vector space, not {0}'.
format(arg0))
if is_Matrix(arg0):
R = arg0.base_ring()
if not R.is_field():
try:
R = R.fraction_field()
except (NotImplementedError, TypeError):
msg = 'matrix must have entries from a field, or a ring with a fraction field, not {0}'
raise TypeError(msg.format(R))
if side == 'right':
arg0 = arg0.transpose()
side = 'left'
arg2 = arg0
arg0 = VectorSpace(R, arg2.nrows())
arg1 = VectorSpace(R, arg2.ncols())
elif is_VectorSpace(arg0):
if not is_VectorSpace(arg1):
msg = 'if first argument is a vector space, then second argument must be a vector space, not {0}'
raise TypeError(msg.format(arg1))
if arg0.base_ring() != arg1.base_ring():
msg = 'vector spaces must have the same field of scalars, not {0} and {1}'
raise TypeError(msg.format(arg0.base_ring(), arg1.base_ring()))
# Now arg0 = domain D, arg1 = codomain C, and
# both are vector spaces with common field of scalars
# use these to make a VectorSpaceHomSpace
# arg2 might be a matrix that began in arg0
D = arg0
C = arg1
H = Hom(D, C, category=None)
# Examine arg2 as the "rule" for the linear transformation
# Pass on matrices, Python functions and lists to homspace call
# Convert symbolic function here, to a matrix
if is_Matrix(arg2):
if side == 'right':
arg2 = arg2.transpose()
elif isinstance(arg2, (list, tuple)):
pass
elif isfunction(arg2):
pass
elif isinstance(arg2, Vector_callable_symbolic_dense):
args = arg2.parent().base_ring()._arguments
exprs = arg2.change_ring(SymbolicRing())
m = len(args)
n = len(exprs)
if m != D.degree():
raise ValueError(
'symbolic function has the wrong number of inputs for domain')
if n != C.degree():
raise ValueError(
'symbolic function has the wrong number of outputs for codomain'
)
arg2 = [[e.coeff(a) for e in exprs] for a in args]
try:
arg2 = matrix(D.base_ring(), m, n, arg2)
except TypeError, e:
msg = 'symbolic function must be linear in all the inputs:\n' + e.args[
0]
raise ValueError(msg)
# have matrix with respect to standard bases, now consider user bases
images = [v * arg2 for v in D.basis()]
try:
arg2 = matrix([C.coordinates(C(a)) for a in images])
except (ArithmeticError, TypeError), e:
msg = 'some image of the function is not in the codomain, because\n' + e.args[
0]
raise ArithmeticError(msg)
