class TestCrossKernelReconstructor(TestCase):
    KERNEL = None
    MEASURED = [13, 37]
    CROSS_KERNEL = [[1, 3], [2, 2], [3, 1]]

    def setUp(self):
        self.kernel_solver = SpyKernelSolverClass()
        self.reconstructor = verbose._VerboseFunctionalFieldReconstructorBase._CrossKernelReconstructor(
            self.kernel_solver(self.KERNEL), self.CROSS_KERNEL)

    def testReconstructsSingleMeasurements(self):
        self.checkCall([1, 1])

    def testReconstructsSingleMeasurementsWithRegularization(self):
        self.checkCall([1, 1], regularization_parameter=1)

    def testReconstructsSerialMeasurements(self):
        self.checkCall([[1, 1], [-1, 2]])

    def test_leave_one_out_methodWithoutRegularization(self):
        self.check_leave_one_out_method()

    def test_leave_one_out_methodWithRegularization(self):
        self.check_leave_one_out_method(regularization_parameter=1)

    def checkCall(self, solution, regularization_parameter=None):
        self.kernel_solver.set_solution(solution)
        expected = np.matmul(self.CROSS_KERNEL, solution)
        self.checkArrayLikeAlmostEqual(
            expected,
            (self.reconstructor(self.MEASURED)
             if regularization_parameter is None else self.reconstructor(
                 self.MEASURED,
                 regularization_parameter=regularization_parameter)))
        self.assertEqual(1, self.kernel_solver.call_counter['__call__'])
        self.check_rhs_and_regularization_parameter_arguments(
            regularization_parameter)

    def check_rhs_and_regularization_parameter_arguments(
            self, regularization_parameter):
        self.checkArrayLikeAlmostEqual(self.MEASURED, self.kernel_solver.rhs)
        if regularization_parameter is None:
            self.assertIsNone(self.kernel_solver.regularization_parameter)
        else:
            self.assertEqual(regularization_parameter,
                             self.kernel_solver.regularization_parameter)

    def check_leave_one_out_method(self, regularization_parameter=None):
        result = np.random.random(2)
        self.kernel_solver.set_leave_one_out_errors(result)
        self.checkArrayAlmostEqual(
            result, (self.reconstructor.leave_one_out_errors(self.MEASURED)
                     if regularization_parameter is None else
                     self.reconstructor.leave_one_out_errors(
                         self.MEASURED,
                         regularization_parameter=regularization_parameter)))
        self.assertEqual(
            1, self.kernel_solver.call_counter['leave_one_out_errors'])
        self.check_rhs_and_regularization_parameter_arguments(
            regularization_parameter)
Exemplo n.º 2
0
 def setUp(self):
     self.measurement_manager = self.MatrixMeasurementManager(self.PROBED)
     self.kernel_solver = SpyKernelSolverClass()
     self.reconstructor = self.PlainKernelSolutionFFR(
         range(self.measurement_manager.number_of_measurements),
         self.measurement_manager,
         KernelSolverClass=self.kernel_solver)
Exemplo n.º 3
0
class TestFunctionalFieldReconstructorMayUseArbitraryKernelSolverClass(
        _TestCase):
    class MatrixMeasurementManager(
            LoadableFunctionalFieldReconstructor.MeasurementManagerBase):
        def __init__(self, probed):
            self._probed = np.array(probed)

        @property
        def number_of_measurements(self):
            return self._probed.shape[1]

        def probe(self, field):
            return self._probed[field]

    class PlainKernelSolutionFFR(LoadableFunctionalFieldReconstructor):
        def _wrap_kernel_solution(self, solution):
            return solution

    PROBED = [[1], [2], [3]]

    def setUp(self):
        self.measurement_manager = self.MatrixMeasurementManager(self.PROBED)
        self.kernel_solver = SpyKernelSolverClass()
        self.reconstructor = self.createLoadableReconstructor(
            self.PlainKernelSolutionFFR,
            range(self.measurement_manager.number_of_measurements),
            self.measurement_manager,
            KernelSolverClass=self.kernel_solver)

    def testNoRegularization(self):
        measurements = [42]
        solution = 'The answer to the universe, life, and everything else'
        self.kernel_solver.set_solution(solution)
        self.assertIs(self.reconstructor(measurements), solution)
        self.assertEqual(1, self.kernel_solver.call_counter['__init__'])
        self.assertEqual(1, self.kernel_solver.call_counter['__call__'])
        self.checkArrayLikeAlmostEqual(self.reconstructor._kernel,
                                       self.kernel_solver.kernel)
        self.checkArrayLikeAlmostEqual(np.reshape(measurements, (-1, 1)),
                                       self.kernel_solver.rhs)
        self.assertEqual(0, self.kernel_solver.regularization_parameter)

    def testRegularization(self):
        measurements = [42]
        regularization_parameter = 1
        solution = 'What do you get if you multiply six by nine?'
        self.kernel_solver.set_solution(solution)
        self.assertIs(
            self.reconstructor(
                measurements,
                regularization_parameter=regularization_parameter), solution)
        self.assertEqual(1, self.kernel_solver.call_counter['__init__'])
        self.assertEqual(1, self.kernel_solver.call_counter['__call__'])
        self.checkArrayLikeAlmostEqual(self.reconstructor._kernel,
                                       self.kernel_solver.kernel)
        self.checkArrayLikeAlmostEqual(np.reshape(measurements, (-1, 1)),
                                       self.kernel_solver.rhs)
        self.assertEqual(regularization_parameter,
                         self.kernel_solver.regularization_parameter)
    def testDeprecationWarning(self):
        with warnings.catch_warnings(record=True) as w:
            warnings.simplefilter("always")

            verbose._CrossKernelReconstructor(SpyKernelSolverClass([[]]), [[]])

            self.assertEqual(1, len(w))
            self.assertTrue(issubclass(w[-1].category, DeprecationWarning))
 def setUp(self):
     self.kernel_solver = SpyKernelSolverClass()
     self.reconstructor = verbose._VerboseFunctionalFieldReconstructorBase._CrossKernelReconstructor(
         self.kernel_solver(self.KERNEL), self.CROSS_KERNEL)