-"""
-Class definitions for all of the symmetric cones (and their superclass,
-:class:`SymmetricCone`) supported by CVXOPT.
-"""
-
-from cvxopt import matrix
-
-from .matrices import eigenvalues, norm
-from . import options
-
-class SymmetricCone:
- """
- An instance of a symmetric (self-dual and homogeneous) cone.
-
- There are three types of symmetric cones supported by CVXOPT:
-
- 1. The nonnegative orthant in the real n-space.
- 2. The Lorentz "ice cream" cone, or the second-order cone.
- 3. The cone of symmetric positive-semidefinite matrices.
-
- This class is intended to encompass them all.
-
- When constructing a single symmetric cone (i.e. not a
- :class:`CartesianProduct` of them), the only information that we
- need is its dimension. We take that dimension as a parameter, and
- store it for later.
-
- Parameters
- ----------
-
- dimension : int
- The dimension of this cone.
-
- Raises
- ------
-
- ValueError
- If you try to create a cone with dimension zero or less.
-
- """
- def __init__(self, dimension):
- """
- A generic constructor for symmetric cones.
- """
- if dimension <= 0:
- raise ValueError('cones must have dimension greater than zero')
-
- self._dimension = dimension
-
-
- def __contains__(self, point):
- """
- Return whether or not ``point`` belongs to this cone.
-
- Parameters
- ----------
-
- point : matrix
- The point to test for membership in this cone.
-
- Raises
- ------
-
- NotImplementedError
- Always, this method must be implemented in subclasses.
-
- Examples
- --------
-
- >>> K = SymmetricCone(5)
- >>> matrix([1,2]) in K
- Traceback (most recent call last):
- ...
- NotImplementedError
-
- """
- raise NotImplementedError
-
-
-
- def dimension(self):
- """
- Return the dimension of this symmetric cone.
-
- The dimension of this symmetric cone is recorded during its
- creation. This method simply returns the recorded value, and
- should not need to be overridden in subclasses. We prefer to do
- any special computation in ``__init__()`` and record the result
- in ``self._dimension``.
-
- Returns
- -------
-
- int
- The stored dimension (from when this cone was constructed)
- of this cone.
-
- Examples
- --------
-
- >>> K = SymmetricCone(5)
- >>> K.dimension()
- 5
-
- """
- return self._dimension
-
-
-class NonnegativeOrthant(SymmetricCone):
- """
- The nonnegative orthant in the given number of dimensions.
-
- Examples
- --------
-
- >>> K = NonnegativeOrthant(3)
- >>> print(K)
- Nonnegative orthant in the real 3-space
-
- """
- def __str__(self):
- """
- Output a human-readable description of myself.
- """
- tpl = 'Nonnegative orthant in the real {:d}-space'
- return tpl.format(self.dimension())
-
-
- def __contains__(self, point):
- """
- Return whether or not ``point`` belongs to this cone.
-
- Since this test is expected to work on points whose components
- are floating point numbers, it doesn't make any sense to
- distinguish between strict and non-strict containment -- the
- test uses a tolerance parameter.
-
- Parameters
- ----------
-
- point : matrix
- A :class:`cvxopt.base.matrix` having dimensions ``(n,1)``
- where ``n`` is the :meth:`dimension` of this cone.
-
- Returns
- -------
-
- bool
-
- ``True`` if ``point`` belongs to this cone, ``False`` otherwise.
-
- Raises
- ------
-
- TypeError
- If ``point`` is not a :class:`cvxopt.base.matrix`.
-
- TypeError
- If ``point`` has the wrong dimensions.
-
- Examples
- --------
-
- All of these coordinates are positive enough:
-
- >>> K = NonnegativeOrthant(3)
- >>> matrix([1,2,3]) in K
- True
-
- The one negative coordinate pushes this point outside of ``K``:
-
- >>> K = NonnegativeOrthant(3)
- >>> matrix([1,-0.1,3]) in K
- False
-
- A boundary point is considered inside of ``K``:
- >>> K = NonnegativeOrthant(3)
- >>> matrix([1,0,3]) in K
- True
-
- Junk arguments don't work:
-
- >>> K = NonnegativeOrthant(3)
- >>> [1,2,3] in K
- Traceback (most recent call last):
- ...
- TypeError: the given point is not a cvxopt.base.matrix
-
- >>> K = NonnegativeOrthant(3)
- >>> matrix([1,2]) in K
- Traceback (most recent call last):
- ...
- TypeError: the given point has the wrong dimensions
-
- """
- if not isinstance(point, matrix):
- raise TypeError('the given point is not a cvxopt.base.matrix')
- if not point.size == (self.dimension(), 1):
- raise TypeError('the given point has the wrong dimensions')
-
- return all([x > -options.ABS_TOL for x in point])
-
-
-
-class IceCream(SymmetricCone):
- """
- The Lorentz "ice cream" cone in the given number of dimensions.
-
- Examples
- --------
-
- >>> K = IceCream(3)
- >>> print(K)
- Lorentz "ice cream" cone in the real 3-space
-
- """
- def __str__(self):
- """
- Output a human-readable description of myself.
- """
- tpl = 'Lorentz "ice cream" cone in the real {:d}-space'
- return tpl.format(self.dimension())
-
-
- def __contains__(self, point):
- """
- Return whether or not ``point`` belongs to this cone.
-
- Since this test is expected to work on points whose components
- are floating point numbers, it doesn't make any sense to
- distinguish between strict and non-strict containment -- the
- test uses a tolerance parameter.
-
- Parameters
- ----------
-
- point : matrix
- A :class:`cvxopt.base.matrix` having dimensions ``(n,1)``
- where ``n`` is the :meth:`dimension` of this cone.
-
- Returns
- -------
-
- bool
-
- ``True`` if ``point`` belongs to this cone, ``False`` otherwise.
-
- Raises
- ------
-
- TypeError
- If ``point`` is not a :class:`cvxopt.base.matrix`.
-
- TypeError
- If ``point`` has the wrong dimensions.
-
- Examples
- --------
-
- This point lies well within the ice cream cone:
-
- >>> K = IceCream(3)
- >>> matrix([1,0.5,0.5]) in K
- True
-
- This one lies on its boundary:
-
- >>> K = IceCream(3)
- >>> matrix([1,0,1]) in K
- True
-
- This point lies entirely outside of the ice cream cone:
-
- >>> K = IceCream(3)
- >>> matrix([1,1,1]) in K
- False
-
- Junk arguments don't work:
-
- >>> K = IceCream(3)
- >>> [1,2,3] in K
- Traceback (most recent call last):
- ...
- TypeError: the given point is not a cvxopt.base.matrix
-
- >>> K = IceCream(3)
- >>> matrix([1,2]) in K
- Traceback (most recent call last):
- ...
- TypeError: the given point has the wrong dimensions
-
- """
- if not isinstance(point, matrix):
- raise TypeError('the given point is not a cvxopt.base.matrix')
- if not point.size == (self.dimension(), 1):
- raise TypeError('the given point has the wrong dimensions')
-
- height = point[0]
- if self.dimension() == 1:
- # In one dimension, the ice cream cone is the nonnegative
- # orthant.
- return height > -options.ABS_TOL
- else:
- radius = point[1:]
- return norm(radius) < (height + options.ABS_TOL)
-
-
-
-class SymmetricPSD(SymmetricCone):
- r"""
- The cone of real symmetric positive-semidefinite matrices.
-
- This cone has a dimension ``n`` associated with it, but we let ``n``
- refer to the dimension of the domain of our matrices and not the
- dimension of the (much larger) space in which the matrices
- themselves live. In other words, our ``n`` is the ``n`` that appears
- in the usual notation :math:`S^{n}` for symmetric matrices.
-
- As a result, the cone ``SymmetricPSD(n)`` lives in a space of dimension
- :math:`\left(n^{2} + n\right)/2)`.
-
- Examples
- --------
-
- >>> K = SymmetricPSD(3)
- >>> print(K)
- Cone of symmetric positive-semidefinite matrices on the real 3-space
- >>> K.dimension()
- 3
-
- """
- def __str__(self):
- """
- Output a human-readable description of myself.
- """
- tpl = 'Cone of symmetric positive-semidefinite matrices ' \
- 'on the real {:d}-space'
- return tpl.format(self.dimension())
-
-
- def __contains__(self, point):
- """
- Return whether or not ``point`` belongs to this cone.
-
- Since this test is expected to work on points whose components
- are floating point numbers, it doesn't make any sense to
- distinguish between strict and non-strict containment -- the
- test uses a tolerance parameter.
-
- Parameters
- ----------
-
- point : matrix
- A :class:`cvxopt.base.matrix` having dimensions ``(n,n)``
- where ``n`` is the :meth:`dimension` of this cone.
-
- Returns
- -------
-
- bool
-
- ``True`` if ``point`` belongs to this cone, ``False`` otherwise.
-
- Raises
- ------
-
- TypeError
- If ``point`` is not a :class:`cvxopt.base.matrix`.
-
- TypeError
- If ``point`` has the wrong dimensions.
-
- Examples
- --------
-
- These all lie in the interior of the Symmetric PSD cone:
-
- >>> K = SymmetricPSD(2)
- >>> matrix([[1,0],[0,1]]) in K
- True
-
- >>> K = SymmetricPSD(3)
- >>> matrix([[2,-1,0],[-1,2,-1],[0,-1,2]]) in K
- True
-
- >>> K = SymmetricPSD(5)
- >>> A = matrix([[5,4,3,2,1],
- ... [4,5,4,3,2],
- ... [3,4,5,4,3],
- ... [2,3,4,5,4],
- ... [1,2,3,4,5]])
- >>> A in K
- True
-
- Boundary points lie in the cone as well:
-
- >>> K = SymmetricPSD(2)
- >>> matrix([[0,0],[0,0]]) in K
- True
-
- >>> K = SymmetricPSD(5)
- >>> A = matrix([[1,0,0,0,0],
- ... [0,1,0,0,0],
- ... [0,0,0,0,0],
- ... [0,0,0,1,0],
- ... [0,0,0,0,1]])
- >>> A in K
- True
-
- However, this matrix has a negative eigenvalue:
-
- >>> K = SymmetricPSD(2)
- >>> A = matrix([[ 1, -2],
- ... [-2, 1]])
- >>> A in K
- False
-
- An asymmetric cone with positive eigenvalues is not in the cone:
-
- >>> K = SymmetricPSD(2)
- >>> A = matrix([[10, 2],
- ... [4, 8]])
- >>> A in K
- False
-
- Junk arguments don't work:
-
- >>> K = SymmetricPSD(2)
- >>> [[1,2],[2,3]] in K
- Traceback (most recent call last):
- ...
- TypeError: the given point is not a cvxopt.base.matrix
-
- >>> K = SymmetricPSD(3)
- >>> matrix([[1,2],[3,4]]) in K
- Traceback (most recent call last):
- ...
- TypeError: the given point has the wrong dimensions
-
- """
- if not isinstance(point, matrix):
- raise TypeError('the given point is not a cvxopt.base.matrix')
- if not point.size == (self.dimension(), self.dimension()):
- raise TypeError('the given point has the wrong dimensions')
- if not point.typecode == 'd':
- point = matrix(point, (self.dimension(), self.dimension()), 'd')
- if not norm(point - point.trans()) < options.ABS_TOL:
- # It's not symmetric.
- return False
- return all([e > -options.ABS_TOL for e in eigenvalues(point)])
-
-
-
-class CartesianProduct(SymmetricCone):
- """
- A cartesian product of symmetric cones, which is itself a symmetric
- cone.
-
- Examples
- --------
-
- >>> K = CartesianProduct(NonnegativeOrthant(3), IceCream(2))
- >>> print(K)
- Cartesian product of dimension 5 with 2 factors:
- * Nonnegative orthant in the real 3-space
- * Lorentz "ice cream" cone in the real 2-space
-
- """
- def __init__(self, *factors):
- my_dimension = sum([f.dimension() for f in factors])
- super().__init__(my_dimension)
- self._factors = factors
-
-
- def __str__(self):
- """
- Output a human-readable description of myself.
- """
- tpl = 'Cartesian product of dimension {:d} with {:d} factors:'
- tpl += '\n * {!s}' * len(self.factors())
- format_args = [self.dimension(), len(self.factors())]
- format_args += list(self.factors())
- return tpl.format(*format_args)
-
-
- def __contains__(self, point):
- """
- Return whether or not ``point`` belongs to this cone.
-
- The ``point`` is expected to be a tuple of points which will be
- tested for membership in this cone's factors. If each point in
- the tuple belongs to its corresponding factor, then the whole
- point belongs to this cone. Otherwise, it doesn't.
-
- Parameters
- ----------
-
- point : tuple of matrix
- A tuple of :class:`cvxopt.base.matrix` corresponding to the
- :meth:`factors` of this cartesian product.
-
- Returns
- -------
-
- bool
-
- ``True`` if ``point`` belongs to this cone, ``False`` otherwise.
-
- Raises
- ------
-
- TypeError
- If ``point`` is not a tuple of :class:`cvxopt.base.matrix`.
-
- TypeError
- If any element of ``point`` has the wrong dimensions.
-
- Examples
- --------
-
- The result depends on how containment is defined for our factors:
-
- >>> K = CartesianProduct(NonnegativeOrthant(3), IceCream(3))
- >>> (matrix([1,2,3]), matrix([1,0.5,0.5])) in K
- True
-
- >>> K = CartesianProduct(NonnegativeOrthant(3), IceCream(3))
- >>> (matrix([0,0,0]), matrix([1,0,1])) in K
- True
-
- >>> K = CartesianProduct(NonnegativeOrthant(3), IceCream(3))
- >>> (matrix([1,1,1]), matrix([1,1,1])) in K
- False
-
- >>> K = CartesianProduct(NonnegativeOrthant(3), IceCream(3))
- >>> (matrix([1,-1,1]), matrix([1,0,1])) in K
- False
-
- Junk arguments don't work:
-
- >>> K = CartesianProduct(NonnegativeOrthant(3), IceCream(3))
- >>> [[1,2,3],[4,5,6]] in K
- Traceback (most recent call last):
- ...
- TypeError: the given point is not a cvxopt.base.matrix
-
- >>> K = CartesianProduct(NonnegativeOrthant(3), IceCream(3))
- >>> (matrix([1,2]), matrix([3,4,5,6])) in K
- Traceback (most recent call last):
- ...
- TypeError: the given point has the wrong dimensions
-
- """
- return all([p in f for (p, f) in zip(point, self.factors())])
-
-
-
- def factors(self):
- """
- Return a tuple containing the factors (in order) of this
- cartesian product.
-
- Returns
- -------
-
- tuple of :class:`SymmetricCone`.
- The factors of this cartesian product.
-
- Examples
- --------
-
- >>> K = CartesianProduct(NonnegativeOrthant(3), IceCream(2))
- >>> len(K.factors())
- 2
-
- """
- return self._factors
-
-
- def cvxopt_dims(self):
- """
- Return a dictionary of dimensions corresponding to the factors
- of this cartesian product. The format of this dictionary is
- described in the CVXOPT user's guide:
-
- http://cvxopt.org/userguide/coneprog.html#linear-cone-programs
-
- Returns
- -------
-
- dict
- A dimension dictionary suitable to feed to CVXOPT.
-
- Examples
- --------
-
- >>> K = CartesianProduct(NonnegativeOrthant(3),
- ... IceCream(2),
- ... IceCream(3))
- >>> d = K.cvxopt_dims()
- >>> (d['l'], d['q'], d['s'])
- (3, [2, 3], [])
-
- """
- dims = {'l':0, 'q':[], 's':[]}
- dims['l'] += sum([K.dimension()
- for K in self.factors()
- if isinstance(K, NonnegativeOrthant)])
- dims['q'] = [K.dimension()
- for K in self.factors()
- if isinstance(K, IceCream)]
- dims['s'] = [K.dimension()
- for K in self.factors()
- if isinstance(K, SymmetricPSD)]
- return dims
-
-