From: Michael Orlitzky Date: Sun, 30 Oct 2016 21:24:30 +0000 (-0400) Subject: Add the condition number of the game to its string representation. X-Git-Tag: 0.1.0~108 X-Git-Url: https://gitweb.michael.orlitzky.com/?p=dunshire.git;a=commitdiff_plain;h=1e02fd12b64e090e0b0ab0d3fecbd9c1b18d0fcf Add the condition number of the game to its string representation. --- diff --git a/dunshire/errors.py b/dunshire/errors.py index 1ecf3dc..61fe43d 100644 --- a/dunshire/errors.py +++ b/dunshire/errors.py @@ -90,7 +90,8 @@ class GameUnsolvableException(Exception): e1 = [1.0000000] [0.1000000], e2 = [3.0000000] - [0.1000000]. + [0.1000000], + Condition((L, K, e1, e2)) = 8.311277. CVXOPT returned: dual infeasibility: None dual objective: 1.0 @@ -190,7 +191,8 @@ class PoorScalingException(Exception): e1 = [1.0000000] [0.1000000], e2 = [3.0000000] - [0.1000000]. + [0.1000000], + Condition((L, K, e1, e2)) = 8.311277. """ def __init__(self, game): diff --git a/dunshire/games.py b/dunshire/games.py index 9610802..46092c3 100644 --- a/dunshire/games.py +++ b/dunshire/games.py @@ -8,7 +8,7 @@ knows how to solve a linear game. from cvxopt import matrix, printing, solvers from .cones import CartesianProduct from .errors import GameUnsolvableException, PoorScalingException -from .matrices import append_col, append_row, identity +from .matrices import append_col, append_row, condition_number, identity from . import options printing.options['dformat'] = options.FLOAT_FORMAT @@ -221,7 +221,8 @@ class SymmetricLinearGame: [ 1], e2 = [ 1] [ 2] - [ 3]. + [ 3], + Condition((L, K, e1, e2)) = 63.669790. Lists can (and probably should) be used for every argument:: @@ -239,7 +240,8 @@ class SymmetricLinearGame: e1 = [ 1] [ 1], e2 = [ 1] - [ 1]. + [ 1], + Condition((L, K, e1, e2)) = 3.414214. The points ``e1`` and ``e2`` can also be passed as some other enumerable type (of the correct length) without much harm, since @@ -261,7 +263,8 @@ class SymmetricLinearGame: e1 = [ 1] [ 1], e2 = [ 1] - [ 1]. + [ 1], + Condition((L, K, e1, e2)) = 3.414214. However, ``L`` will always be intepreted as a list of rows, even if it is passed as a :class:`cvxopt.base.matrix` which is @@ -282,7 +285,8 @@ class SymmetricLinearGame: e1 = [ 1] [ 1], e2 = [ 1] - [ 1]. + [ 1], + Condition((L, K, e1, e2)) = 12.147542. >>> L = cvxopt.matrix(L) >>> print(L) [ 1 3] @@ -297,7 +301,8 @@ class SymmetricLinearGame: e1 = [ 1] [ 1], e2 = [ 1] - [ 1]. + [ 1], + Condition((L, K, e1, e2)) = 12.147542. """ def __init__(self, L, K, e1, e2): @@ -319,6 +324,10 @@ class SymmetricLinearGame: if not self._e2 in K: raise ValueError('the point e2 must lie in the interior of K') + # Cached result of the self._zero() method. + self._zero_col = None + + def __str__(self): """ Return a string representation of this game. @@ -327,11 +336,51 @@ class SymmetricLinearGame: ' L = {:s},\n' \ ' K = {!s},\n' \ ' e1 = {:s},\n' \ - ' e2 = {:s}.' + ' e2 = {:s},\n' \ + ' Condition((L, K, e1, e2)) = {:f}.' indented_L = '\n '.join(str(self._L).splitlines()) indented_e1 = '\n '.join(str(self._e1).splitlines()) indented_e2 = '\n '.join(str(self._e2).splitlines()) - return tpl.format(indented_L, str(self._K), indented_e1, indented_e2) + + return tpl.format(indented_L, + str(self._K), + indented_e1, + indented_e2, + self._condition()) + + + def _zero(self): + """ + Return a column of zeros that fits ``K``. + + This is used in our CVXOPT construction. + """ + if self._zero_col is None: + # Cache it, it's constant. + self._zero_col = matrix(0, (self._K.dimension(), 1), tc='d') + return self._zero_col + + + def _A(self): + """ + Return the matrix ``A`` used in our CVXOPT construction. + + This matrix ``A`` appears on the right-hand side of ``Ax = b`` + in the statement of the CVXOPT conelp program. + """ + return matrix([0, self._e2], (1, self._K.dimension() + 1), 'd') + + + def _G(self): + r""" + Return the matrix ``G`` used in our CVXOPT construction. + + Thus matrix ``G``that appears on the left-hand side of ``Gx + s = h`` + in the statement of the CVXOPT conelp program. + """ + I = identity(self._K.dimension()) + return append_row(append_col(self._zero(), -I), + append_col(self._e1, -self._L)) def solution(self): @@ -407,30 +456,19 @@ class SymmetricLinearGame: # Ax = b in the statement of the CVXOPT conelp program. b = matrix([1], tc='d') - # A column of zeros that fits K. - zero = matrix(0, (self._K.dimension(), 1), tc='d') - # The column vector "h" that appears on the right-hand side of # Gx + s = h in the statement of the CVXOPT conelp program. - h = matrix([zero, zero]) + h = matrix([self._zero(), self._zero()]) # The column vector "c" that appears in the objective function # value in the statement of the CVXOPT conelp program. - c = matrix([-1, zero]) - - # The matrix "G" that appears on the left-hand side of Gx + s = h - # in the statement of the CVXOPT conelp program. - G = append_row(append_col(zero, -identity(self._K.dimension())), - append_col(self._e1, -self._L)) - - # The matrix "A" that appears on the right-hand side of Ax = b - # in the statement of the CVXOPT conelp program. - A = matrix([0, self._e2], (1, self._K.dimension() + 1), 'd') + c = matrix([-1, self._zero()]) # Actually solve the thing and obtain a dictionary describing # what happened. try: - soln_dict = solvers.conelp(c, G, h, C.cvxopt_dims(), A, b) + soln_dict = solvers.conelp(c, self._G(), h, + C.cvxopt_dims(), self._A(), b) except ValueError as e: if str(e) == 'math domain error': # Oops, CVXOPT tried to take the square root of a @@ -475,6 +513,36 @@ class SymmetricLinearGame: return Solution(p1_value, p1_optimal, p2_optimal) + def _condition(self): + r""" + Return the condition number of this game. + + In the CVXOPT construction of this game, two matrices ``G`` and + ``A`` appear. When those matrices are nasty, numerical problems + can show up. We define the condition number of this game to be + the sum of the condition numbers of ``G`` and ``A`` in the + CVXOPT construction. If the condition number of this game is + high, then you can expect numerical difficulty (such as + :class:`PoorScalingException`). + + Examples + -------- + + >>> from dunshire import * + >>> K = NonnegativeOrthant(1) + >>> L = [[1]] + >>> e1 = [1] + >>> e2 = e1 + >>> SLG = SymmetricLinearGame(L, K, e1, e2) + >>> actual = SLG._condition() + >>> expected = 3.6180339887498953 + >>> abs(actual - expected) < options.ABS_TOL + True + + """ + return condition_number(self._G()) + condition_number(self._A()) + + def dual(self): r""" Return the dual game to this game. @@ -504,7 +572,8 @@ class SymmetricLinearGame: [ 3], e2 = [ 1] [ 1] - [ 1]. + [ 1], + Condition((L, K, e1, e2)) = 88.953530. """ # We pass ``self._L`` right back into the constructor, because