-# These few are used only for tests.
-from math import sqrt
-from random import randint, uniform
+"""
+Unit tests for the :class:`SymmetricLinearGame` class.
+"""
+
from unittest import TestCase
-from cvxopt import matrix
-from dunshire.cones import NonnegativeOrthant, IceCream
from dunshire.games import SymmetricLinearGame
-from dunshire.matrices import (append_col, append_row, eigenvalues_re,
- identity, inner_product)
+from dunshire.matrices import eigenvalues_re, inner_product, norm
from dunshire import options
+from .randomgen import (random_icecream_game, random_ll_icecream_game,
+ random_ll_orthant_game, random_nn_scaling,
+ random_orthant_game, random_positive_orthant_game,
+ random_translation)
-def _random_matrix(dims):
- """
- Generate a random square (``dims``-by-``dims``) matrix. This is used
- only by the :class:`SymmetricLinearGameTest` class.
- """
- return matrix([[uniform(-10, 10) for i in range(dims)]
- for j in range(dims)])
-def _random_nonnegative_matrix(dims):
+# Tell pylint to shut up about the large number of methods.
+class SymmetricLinearGameTest(TestCase): # pylint: disable=R0904
"""
- Generate a random square (``dims``-by-``dims``) matrix with
- nonnegative entries. This is used only by the
- :class:`SymmetricLinearGameTest` class.
+ Tests for the SymmetricLinearGame and Solution classes.
"""
- L = _random_matrix(dims)
- return matrix([abs(entry) for entry in L], (dims, dims))
+ def assert_within_tol(self, first, second, modifier=1):
+ """
+ Test that ``first`` and ``second`` are equal within a multiple of
+ our default tolerances.
-def _random_diagonal_matrix(dims):
- """
- Generate a random square (``dims``-by-``dims``) matrix with nonzero
- entries only on the diagonal. This is used only by the
- :class:`SymmetricLinearGameTest` class.
- """
- return matrix([[uniform(-10, 10)*int(i == j) for i in range(dims)]
- for j in range(dims)])
+ Parameters
+ ----------
+ first : float
+ The first number to compare.
-def _random_skew_symmetric_matrix(dims):
- """
- Generate a random skew-symmetrix (``dims``-by-``dims``) matrix.
+ second : float
+ The second number to compare.
- Examples
- --------
+ modifier : float
+ A scaling factor (default: 1) applied to the default
+ tolerance for this comparison. If you have a poorly-
+ conditioned matrix, for example, you may want to set this
+ greater than one.
- >>> from dunshire.matrices import norm
- >>> A = _random_skew_symmetric_matrix(randint(1, 10))
- >>> norm(A + A.trans()) < options.ABS_TOL
- True
+ """
+ self.assertTrue(abs(first - second) < options.ABS_TOL*modifier)
- """
- strict_ut = [[uniform(-10, 10)*int(i < j) for i in range(dims)]
- for j in range(dims)]
- strict_ut = matrix(strict_ut, (dims, dims))
- return strict_ut - strict_ut.trans()
+ def test_solutions_dont_change_orthant(self):
+ """
+ If we solve the same game twice over the nonnegative orthant,
+ then we should get the same solution both times. The solution to
+ a game is not unique, but the process we use is (as far as we
+ know) deterministic.
+ """
+ G = random_orthant_game()
+ self.assert_solutions_dont_change(G)
+ def test_solutions_dont_change_icecream(self):
+ """
+ If we solve the same game twice over the ice-cream cone, then we
+ should get the same solution both times. The solution to a game
+ is not unique, but the process we use is (as far as we know)
+ deterministic.
+ """
+ G = random_icecream_game()
+ self.assert_solutions_dont_change(G)
-def _random_lyapunov_like_icecream(dims):
- """
- Generate a random Lyapunov-like matrix over the ice-cream cone in
- ``dims`` dimensions.
- """
- a = matrix([uniform(-10, 10)], (1, 1))
- b = matrix([uniform(-10, 10) for idx in range(dims-1)], (dims-1, 1))
- D = _random_skew_symmetric_matrix(dims-1) + a*identity(dims-1)
- row1 = append_col(a, b.trans())
- row2 = append_col(b, D)
- return append_row(row1, row2)
+ def assert_solutions_dont_change(self, G):
+ """
+ Solve ``G`` twice and check that the solutions agree.
+ """
+ soln1 = G.solution()
+ soln2 = G.solution()
+ p1_diff = norm(soln1.player1_optimal() - soln2.player1_optimal())
+ p2_diff = norm(soln1.player2_optimal() - soln2.player2_optimal())
+ gv_diff = abs(soln1.game_value() - soln2.game_value())
+ p1_close = p1_diff < options.ABS_TOL
+ p2_close = p2_diff < options.ABS_TOL
+ gv_close = gv_diff < options.ABS_TOL
-def _random_orthant_params():
- """
- Generate the ``L``, ``K``, ``e1``, and ``e2`` parameters for a
- random game over the nonnegative orthant. This is only used by
- the :class:`SymmetricLinearGameTest` class.
- """
- ambient_dim = randint(1, 10)
- K = NonnegativeOrthant(ambient_dim)
- e1 = [uniform(0.5, 10) for idx in range(K.dimension())]
- e2 = [uniform(0.5, 10) for idx in range(K.dimension())]
- L = _random_matrix(K.dimension())
- return (L, K, matrix(e1), matrix(e2))
+ self.assertTrue(p1_close and p2_close and gv_close)
-def _random_icecream_params():
- """
- Generate the ``L``, ``K``, ``e1``, and ``e2`` parameters for a
- random game over the ice cream cone. This is only used by
- the :class:`SymmetricLinearGameTest` class.
- """
- # Use a minimum dimension of two to avoid divide-by-zero in
- # the fudge factor we make up later.
- ambient_dim = randint(2, 10)
- K = IceCream(ambient_dim)
- e1 = [1] # Set the "height" of e1 to one
- e2 = [1] # And the same for e2
-
- # If we choose the rest of the components of e1,e2 randomly
- # between 0 and 1, then the largest the squared norm of the
- # non-height part of e1,e2 could be is the 1*(dim(K) - 1). We
- # need to make it less than one (the height of the cone) so
- # that the whole thing is in the cone. The norm of the
- # non-height part is sqrt(dim(K) - 1), and we can divide by
- # twice that.
- fudge_factor = 1.0 / (2.0*sqrt(K.dimension() - 1.0))
- e1 += [fudge_factor*uniform(0, 1) for idx in range(K.dimension() - 1)]
- e2 += [fudge_factor*uniform(0, 1) for idx in range(K.dimension() - 1)]
- L = _random_matrix(K.dimension())
-
- return (L, K, matrix(e1), matrix(e2))
+ def assert_player1_start_valid(self, G):
+ """
+ Ensure that player one's starting point satisfies both the
+ equality and cone inequality in the CVXOPT primal problem.
+ """
+ x = G.player1_start()['x']
+ s = G.player1_start()['s']
+ s1 = s[0:G.dimension()]
+ s2 = s[G.dimension():]
+ self.assert_within_tol(norm(G.A()*x - G.b()), 0)
+ self.assertTrue((s1, s2) in G.C())
-# Tell pylint to shut up about the large number of methods.
-class SymmetricLinearGameTest(TestCase): # pylint: disable=R0904
- """
- Tests for the SymmetricLinearGame and Solution classes.
- """
- def assert_within_tol(self, first, second):
+ def test_player1_start_valid_orthant(self):
"""
- Test that ``first`` and ``second`` are equal within our default
- tolerance.
+ Ensure that player one's starting point is feasible over the
+ nonnegative orthant.
"""
- self.assertTrue(abs(first - second) < options.ABS_TOL)
+ G = random_orthant_game()
+ self.assert_player1_start_valid(G)
- def assert_norm_within_tol(self, first, second):
+ def test_player1_start_valid_icecream(self):
"""
- Test that ``first`` and ``second`` vectors are equal in the
- sense that the norm of their difference is within our default
- tolerance.
+ Ensure that player one's starting point is feasible over the
+ ice-cream cone.
"""
- self.assert_within_tol(norm(first - second), 0)
+ G = random_icecream_game()
+ self.assert_player1_start_valid(G)
- def assert_solution_exists(self, L, K, e1, e2):
+ def assert_player2_start_valid(self, G):
"""
- Given the parameters needed to construct a SymmetricLinearGame,
- ensure that that game has a solution.
+ Check that player two's starting point satisfies both the
+ cone inequality in the CVXOPT dual problem.
"""
- # The matrix() constructor assumes that ``L`` is a list of
- # columns, so we transpose it to agree with what
- # SymmetricLinearGame() thinks.
- G = SymmetricLinearGame(L.trans(), K, e1, e2)
- soln = G.solution()
-
- expected = inner_product(L*soln.player1_optimal(),
- soln.player2_optimal())
- self.assert_within_tol(soln.game_value(), expected)
+ z = G.player2_start()['z']
+ z1 = z[0:G.dimension()]
+ z2 = z[G.dimension():]
+ self.assertTrue((z1, z2) in G.C())
- def test_solution_exists_orthant(self):
+ def test_player2_start_valid_orthant(self):
"""
- Every linear game has a solution, so we should be able to solve
- every symmetric linear game over the NonnegativeOrthant. Pick
- some parameters randomly and give it a shot. The resulting
- optimal solutions should give us the optimal game value when we
- apply the payoff operator to them.
+ Ensure that player two's starting point is feasible over the
+ nonnegative orthant.
"""
- (L, K, e1, e2) = _random_orthant_params()
- self.assert_solution_exists(L, K, e1, e2)
+ G = random_orthant_game()
+ self.assert_player2_start_valid(G)
- def test_solution_exists_icecream(self):
+ def test_player2_start_valid_icecream(self):
"""
- Like :meth:`test_solution_exists_nonnegative_orthant`, except
- over the ice cream cone.
+ Ensure that player two's starting point is feasible over the
+ ice-cream cone.
"""
- (L, K, e1, e2) = _random_icecream_params()
- self.assert_solution_exists(L, K, e1, e2)
+ G = random_icecream_game()
+ self.assert_player2_start_valid(G)
- def test_negative_value_z_operator(self):
+ def test_condition_lower_bound(self):
"""
- Test the example given in Gowda/Ravindran of a Z-matrix with
- negative game value on the nonnegative orthant.
+ Ensure that the condition number of a game is greater than or
+ equal to one.
+
+ It should be safe to compare these floats directly: we compute
+ the condition number as the ratio of one nonnegative real number
+ to a smaller nonnegative real number.
"""
- K = NonnegativeOrthant(2)
- e1 = [1, 1]
- e2 = e1
- L = [[1, -2], [-2, 1]]
- G = SymmetricLinearGame(L, K, e1, e2)
- self.assertTrue(G.solution().game_value() < -options.ABS_TOL)
+ G = random_orthant_game()
+ self.assertTrue(G.condition() >= 1.0)
+ G = random_icecream_game()
+ self.assertTrue(G.condition() >= 1.0)
- def assert_scaling_works(self, L, K, e1, e2):
+ def assert_scaling_works(self, G):
"""
Test that scaling ``L`` by a nonnegative number scales the value
of the game by the same number.
"""
- game1 = SymmetricLinearGame(L, K, e1, e2)
- value1 = game1.solution().game_value()
-
- alpha = uniform(0.1, 10)
- game2 = SymmetricLinearGame(alpha*L, K, e1, e2)
- value2 = game2.solution().game_value()
- self.assert_within_tol(alpha*value1, value2)
+ (alpha, H) = random_nn_scaling(G)
+ soln1 = G.solution()
+ soln2 = H.solution()
+ value1 = soln1.game_value()
+ value2 = soln2.game_value()
+ modifier1 = G.tolerance_scale(soln1)
+ modifier2 = H.tolerance_scale(soln2)
+ modifier = max(modifier1, modifier2)
+ self.assert_within_tol(alpha*value1, value2, modifier)
def test_scaling_orthant(self):
Test that scaling ``L`` by a nonnegative number scales the value
of the game by the same number over the nonnegative orthant.
"""
- (L, K, e1, e2) = _random_orthant_params()
- self.assert_scaling_works(L, K, e1, e2)
+ G = random_orthant_game()
+ self.assert_scaling_works(G)
def test_scaling_icecream(self):
The same test as :meth:`test_nonnegative_scaling_orthant`,
except over the ice cream cone.
"""
- (L, K, e1, e2) = _random_icecream_params()
- self.assert_scaling_works(L, K, e1, e2)
+ G = random_icecream_game()
+ self.assert_scaling_works(G)
- def assert_translation_works(self, L, K, e1, e2):
+ def assert_translation_works(self, G):
"""
Check that translating ``L`` by alpha*(e1*e2.trans()) increases
the value of the associated game by alpha.
"""
# We need to use ``L`` later, so make sure we transpose it
# before passing it in as a column-indexed matrix.
- game1 = SymmetricLinearGame(L.trans(), K, e1, e2)
- soln1 = game1.solution()
+ soln1 = G.solution()
value1 = soln1.game_value()
x_bar = soln1.player1_optimal()
y_bar = soln1.player2_optimal()
- alpha = uniform(-10, 10)
- tensor_prod = e1*e2.trans()
-
# This is the "correct" representation of ``M``, but COLUMN
# indexed...
- M = L + alpha*tensor_prod
-
- # so we have to transpose it when we feed it to the constructor.
- game2 = SymmetricLinearGame(M.trans(), K, e1, e2)
- value2 = game2.solution().game_value()
+ (alpha, H) = random_translation(G)
+ value2 = H.solution().game_value()
- self.assert_within_tol(value1 + alpha, value2)
+ modifier = G.tolerance_scale(soln1)
+ self.assert_within_tol(value1 + alpha, value2, modifier)
# Make sure the same optimal pair works.
- self.assert_within_tol(value2, inner_product(M*x_bar, y_bar))
+ self.assert_within_tol(value2, H.payoff(x_bar, y_bar), modifier)
def test_translation_orthant(self):
"""
Test that translation works over the nonnegative orthant.
"""
- (L, K, e1, e2) = _random_orthant_params()
- self.assert_translation_works(L, K, e1, e2)
+ G = random_orthant_game()
+ self.assert_translation_works(G)
def test_translation_icecream(self):
The same as :meth:`test_translation_orthant`, except over the
ice cream cone.
"""
- (L, K, e1, e2) = _random_icecream_params()
- self.assert_translation_works(L, K, e1, e2)
+ G = random_icecream_game()
+ self.assert_translation_works(G)
- def assert_opposite_game_works(self, L, K, e1, e2):
+ def assert_opposite_game_works(self, G):
"""
Check the value of the "opposite" game that gives rise to a
value that is the negation of the original game. Comes from
some corollary.
"""
- # We need to use ``L`` later, so make sure we transpose it
- # before passing it in as a column-indexed matrix.
- game1 = SymmetricLinearGame(L.trans(), K, e1, e2)
-
# This is the "correct" representation of ``M``, but
# COLUMN indexed...
- M = -L.trans()
+ M = -G.L().trans()
# so we have to transpose it when we feed it to the constructor.
- game2 = SymmetricLinearGame(M.trans(), K, e2, e1)
+ # Note: the condition number of ``H`` should be comparable to ``G``.
+ H = SymmetricLinearGame(M.trans(), G.K(), G.e2(), G.e1())
- soln1 = game1.solution()
+ soln1 = G.solution()
x_bar = soln1.player1_optimal()
y_bar = soln1.player2_optimal()
- soln2 = game2.solution()
+ soln2 = H.solution()
- self.assert_within_tol(-soln1.game_value(), soln2.game_value())
+ modifier = G.tolerance_scale(soln1)
+ self.assert_within_tol(-soln1.game_value(),
+ soln2.game_value(),
+ modifier)
- # Make sure the switched optimal pair works.
+ # Make sure the switched optimal pair works. Since x_bar and
+ # y_bar come from G, we use the same modifier.
self.assert_within_tol(soln2.game_value(),
- inner_product(M*y_bar, x_bar))
+ H.payoff(y_bar, x_bar),
+ modifier)
+
def test_opposite_game_orthant(self):
Test the value of the "opposite" game over the nonnegative
orthant.
"""
- (L, K, e1, e2) = _random_orthant_params()
- self.assert_opposite_game_works(L, K, e1, e2)
+ G = random_orthant_game()
+ self.assert_opposite_game_works(G)
def test_opposite_game_icecream(self):
Like :meth:`test_opposite_game_orthant`, except over the
ice-cream cone.
"""
- (L, K, e1, e2) = _random_icecream_params()
- self.assert_opposite_game_works(L, K, e1, e2)
+ G = random_icecream_game()
+ self.assert_opposite_game_works(G)
- def assert_orthogonality(self, L, K, e1, e2):
+ def assert_orthogonality(self, G):
"""
Two orthogonality relations hold at an optimal solution, and we
check them here.
"""
- # We need to use ``L`` later, so make sure we transpose it
- # before passing it in as a column-indexed matrix.
- game = SymmetricLinearGame(L.trans(), K, e1, e2)
- soln = game.solution()
+ soln = G.solution()
x_bar = soln.player1_optimal()
y_bar = soln.player2_optimal()
value = soln.game_value()
- ip1 = inner_product(y_bar, L*x_bar - value*e1)
- self.assert_within_tol(ip1, 0)
+ ip1 = inner_product(y_bar, G.L()*x_bar - value*G.e1())
+ ip2 = inner_product(value*G.e2() - G.L().trans()*y_bar, x_bar)
- ip2 = inner_product(value*e2 - L.trans()*y_bar, x_bar)
- self.assert_within_tol(ip2, 0)
+ modifier = G.tolerance_scale(soln)
+ self.assert_within_tol(ip1, 0, modifier)
+ self.assert_within_tol(ip2, 0, modifier)
def test_orthogonality_orthant(self):
Check the orthgonality relationships that hold for a solution
over the nonnegative orthant.
"""
- (L, K, e1, e2) = _random_orthant_params()
- self.assert_orthogonality(L, K, e1, e2)
+ G = random_orthant_game()
+ self.assert_orthogonality(G)
def test_orthogonality_icecream(self):
Check the orthgonality relationships that hold for a solution
over the ice-cream cone.
"""
- (L, K, e1, e2) = _random_icecream_params()
- self.assert_orthogonality(L, K, e1, e2)
+ G = random_icecream_game()
+ self.assert_orthogonality(G)
def test_positive_operator_value(self):
This test theoretically applies to the ice-cream cone as well,
but we don't know how to make positive operators on that cone.
"""
- (K, e1, e2) = _random_orthant_params()[1:]
- L = _random_nonnegative_matrix(K.dimension())
-
- game = SymmetricLinearGame(L, K, e1, e2)
- self.assertTrue(game.solution().game_value() >= -options.ABS_TOL)
+ G = random_positive_orthant_game()
+ self.assertTrue(G.solution().game_value() >= -options.ABS_TOL)
- def assert_lyapunov_works(self, L, K, e1, e2):
+ def assert_lyapunov_works(self, G):
"""
Check that Lyapunov games act the way we expect.
"""
- game = SymmetricLinearGame(L, K, e1, e2)
- soln = game.solution()
+ soln = G.solution()
# We only check for positive/negative stability if the game
# value is not basically zero. If the value is that close to
# zero, we just won't check any assertions.
- eigs = eigenvalues_re(L)
+ #
+ # See :meth:`assert_within_tol` for an explanation of the
+ # fudge factors.
+ eigs = eigenvalues_re(G.L())
+
if soln.game_value() > options.ABS_TOL:
# L should be positive stable
positive_stable = all([eig > -options.ABS_TOL for eig in eigs])
negative_stable = all([eig < options.ABS_TOL for eig in eigs])
self.assertTrue(negative_stable)
- # The dual game's value should always equal the primal's.
- dualsoln = game.dual().solution()
- self.assert_within_tol(dualsoln.game_value(), soln.game_value())
+ dualsoln = G.dual().solution()
+ mod = G.tolerance_scale(soln)
+ self.assert_within_tol(dualsoln.game_value(), soln.game_value(), mod)
def test_lyapunov_orthant(self):
"""
Test that a Lyapunov game on the nonnegative orthant works.
"""
- (K, e1, e2) = _random_orthant_params()[1:]
- L = _random_diagonal_matrix(K.dimension())
-
- self.assert_lyapunov_works(L, K, e1, e2)
+ G = random_ll_orthant_game()
+ self.assert_lyapunov_works(G)
def test_lyapunov_icecream(self):
"""
Test that a Lyapunov game on the ice-cream cone works.
"""
- (K, e1, e2) = _random_icecream_params()[1:]
- L = _random_lyapunov_like_icecream(K.dimension())
-
- self.assert_lyapunov_works(L, K, e1, e2)
+ G = random_ll_icecream_game()
+ self.assert_lyapunov_works(G)