예제 #1
0
파일: test_limit.py 프로젝트: tgag17/zfit
def test_rect_limits_1d(graph, rect_limits, testclass):
    def test(allow_graph=True):
        limit = testclass(rect_limits)
        limit2 = testclass(rect_limits=rect_limits)

        lower, upper = limit.rect_limits
        lower2, upper2 = limit2.rect_limits
        assert limit.has_rect_limits
        inside = limit.inside(2)
        inside2 = limit.inside(2, guarantee_limits=True)
        outside = limit.inside(4)
        if graph:
            equal = limit.equal(limit2, allow_graph=allow_graph)
            less_equal = limit.less_equal(limit2, allow_graph=allow_graph)
        else:
            equal = limit == limit2
            less_equal = limit <= limit2

        return lower, upper, lower2, upper2, inside, inside2, outside, equal, less_equal

    if graph:
        test = z.function(test)
    lower, upper, lower2, upper2, inside, inside2, outside, equal, less_equal = test(
    )
    assert equal
    assert less_equal
    assert lower, upper == rect_limits
    assert lower2, upper2 == rect_limits
    assert inside
    assert inside2
    assert not outside
예제 #2
0
def test_reorder_x(graph, testclass):
    x = tf.constant([2, 3, 4, 1], dtype=tf.float64)

    def test():
        x_all = []
        obs = ['a', 'b', 'c', 'd']
        x_obs = ['b', 'c', 'd', 'a']
        func_obs = [
            'd',
            'a',
            'b',
            'c',
        ]
        coords = testclass(obs)
        x_all.append(coords.reorder_x(x, x_obs=x_obs))
        x_all.append(coords.reorder_x(x, func_obs=func_obs))

        axes = [0, 1, 2, 3]
        x_axes = [1, 2, 3, 0]
        func_axes = [3, 0, 1, 2]
        coords = testclass(axes=axes)
        x_all.append(coords.reorder_x(x, x_axes=x_axes))
        x_all.append(coords.reorder_x(x, func_axes=func_axes))

        coords = testclass(obs=obs, axes=axes)
        x_all.append(coords.reorder_x(x, x_obs=x_obs, x_axes=x_axes))
        x_all.append(
            coords.reorder_x(x, func_obs=func_obs, func_axes=func_axes))

        coords = testclass(obs=obs, axes=axes)
        x_all.append(coords.reorder_x(x, x_obs=x_obs))
        x_all.append(coords.reorder_x(x, func_obs=func_obs))

        coords = testclass(obs)
        x_all.append(coords.reorder_x(x, x_obs=x_obs, x_axes=x_axes))
        x_all.append(
            coords.reorder_x(x, func_obs=func_obs, func_axes=func_axes))

        with pytest.raises(ValueError):
            coords.reorder_x(x, x_axes=x_axes)
        with pytest.raises(ValueError):
            coords.reorder_x(x, func_axes=func_axes)

        coords = testclass(axes=axes)
        with pytest.raises(ValueError):
            coords.reorder_x(x, x_obs=x_obs)
        with pytest.raises(ValueError):
            coords.reorder_x(x, func_obs=func_obs)

        return x_all

    if graph:
        test = z.function(test)
    all_x = test()
    true_x = tf.constant([1, 2, 3, 4], dtype=tf.float64)
    for x in all_x:
        assert np.allclose(x, true_x)
예제 #3
0
파일: test_limit.py 프로젝트: zfit/zfit
def test_less_equal(graph, limit_fn, testclass):
    def test(limit_fn=None, allow_graph=True):
        limit = testclass(limit_fn=limit_fn, rect_limits=rect_limits)
        limit2 = testclass(limit_fn=limit_fn, rect_limits=rect_limit_enlarged)

        assert limit.has_rect_limits ^ bool(limit_fn)
        assert limit.has_limits
        assert limit.limits_are_set
        assert not limit.limits_are_false
        inside = limit.inside(2)
        inside2 = limit.inside(2, guarantee_limits=True)
        outside = limit.inside(4)

        assert limit2.has_rect_limits ^ bool(limit_fn)
        assert limit2.has_limits
        assert limit2.limits_are_set
        assert not limit2.limits_are_false
        inside21 = limit2.inside(2)
        inside22 = limit2.inside(2, guarantee_limits=True)
        outside2 = limit2.inside(4)
        if graph:
            equal = limit.equal(limit2, allow_graph=allow_graph)
        else:
            equal = limit == limit2

        return inside, inside2, outside, equal, inside21, inside22, outside2

    if graph:
        test = z.function(test)
    inside, inside2, outside, equal, inside21, inside22, outside2 = test(
        limit_fn=limit_fn)
    assert not (
        equal ^ bool(limit_fn)
    )  # if a limit_fn is specified, this has precedency over the rect
    assert inside
    assert inside2
    assert not outside
    assert inside21
    assert inside22
    assert bool(outside2) ^ bool(limit_fn)  # if limit_fn, this is outside
예제 #4
0
파일: test_limit.py 프로젝트: zfit/zfit
def test_limits_1d(graph, testclass):
    def test(allow_graph=True):
        limit = testclass(limit_fn=inside_rect_limits, rect_limits=rect_limits)
        limit2 = testclass(limit_fn=inside_rect_limits,
                           rect_limits=rect_limit_enlarged)

        assert not limit.has_rect_limits
        assert limit.has_limits
        assert limit.limits_are_set
        assert not limit.limits_are_false
        inside = limit.inside(2)
        inside2 = limit.inside(2, guarantee_limits=True)
        outside = limit.inside(4)

        assert not limit2.has_rect_limits
        assert limit2.has_limits
        assert limit2.limits_are_set
        assert not limit2.limits_are_false
        inside21 = limit2.inside(2)
        inside22 = limit2.inside(2, guarantee_limits=True)
        outside2 = limit2.inside(4)
        if graph:
            equal = limit.equal(limit2, allow_graph=allow_graph)
        else:
            equal = limit == limit2

        return inside, inside2, outside, equal, inside21, inside22, outside2

    if graph:
        test = z.function(test)
    inside, inside2, outside, equal, inside21, inside22, outside2 = test()
    assert equal
    assert inside
    assert inside2
    assert not outside
    assert inside21
    assert inside22
    assert not outside2
예제 #5
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def test_numerical_hessian(graph):
    param1 = zfit.Parameter('param1', 4.)
    param2 = zfit.Parameter('param2', 5.)
    param3 = zfit.Parameter('param3', 2.)

    def func1():
        return param1 * param2**2 + param3**param1

    def create_derivatives(func1, params):
        num_hessian_diag = numerical_hessian(func1,
                                             params=params,
                                             hessian='diag')
        num_hessian = numerical_hessian(func1, params=params)
        tf_hessian_diag = autodiff_hessian(func1,
                                           params=params,
                                           hessian='diag')
        tf_hessian = autodiff_hessian(func1, params=params)
        return num_hessian, num_hessian_diag, tf_hessian, tf_hessian_diag

    params = [param1, param2, param3]
    if graph:
        create_derivatives = z.function(create_derivatives)
    num_hessian, num_hessian_diag, tf_hessian, tf_hessian_diag = create_derivatives(
        func1, params)
    np.testing.assert_allclose(num_hessian, tf_hessian, rtol=1e-4, atol=1e-10)
    tf_hessian_diag_from_hessian = [
        tf_hessian[i, i] for i in range(len(params))
    ]
    np.testing.assert_allclose(tf_hessian_diag_from_hessian,
                               tf_hessian_diag,
                               rtol=1e-4,
                               atol=1e-10)
    np.testing.assert_allclose(num_hessian_diag,
                               tf_hessian_diag,
                               rtol=1e-4,
                               atol=1e-10)
예제 #6
0
파일: test_pdf_kde.py 프로젝트: zfit/zfit
def test_all_kde(kdetype, npoints, jit, request):
    import zfit

    full = request.config.getoption("--longtests")
    full = full or request.config.getoption("--longtests-kde")
    cfg = create_kde(kdetype=kdetype, npoints=npoints, cfgonly=True, full=full)
    print(cfg)
    kdetype = kdetype, npoints
    if jit:
        run_jit = z.function(_run)
        (
            expected_integral,
            integral,
            name,
            prob,
            prob_true,
            rel_tol,
            sample,
            sample2,
            x,
            name,
            data,
        ) = run_jit(kdetype, full=full)
    else:

        (
            expected_integral,
            integral,
            name,
            prob,
            prob_true,
            rel_tol,
            sample,
            sample2,
            x,
            name,
            data,
        ) = _run(kdetype, full=full)

    expected_integral = zfit.run(expected_integral)

    if not jit:
        import matplotlib.pyplot as plt

        plt.figure()
        kernel_used = cfg.get("kernel")
        if kernel_used is not None:
            kernel_print = f", kernel={kernel_used.__name__}"
        else:
            kernel_print = ""
        bandwidth_printready = cfg.get("bandwidth")
        if isinstance(bandwidth_printready, ZfitParameter):
            bandwidth_printready = f"Param({float(bandwidth_printready.value())}"
        if bandwidth_printready is None:
            bandwidth_print = ""
        else:
            bandwidth_print = f", h={bandwidth_printready}"

        num_grid_points = cfg.get("num_grid_points")
        if num_grid_points is not None:
            grid_print = f", grid={num_grid_points}"
        else:
            grid_print = ""
        binning_method = cfg.get("binning_method")
        if binning_method is not None:
            binning_print = f", binning={binning_method}"
        else:
            binning_print = ""
        weights = cfg.get("weights")
        if weights is not None:
            weights_print = ", weighted"
        else:
            weights_print = ""
        npoints_plot = cfg.get("npoints", kdetype[1])
        plt.title(
            f"{name} with {npoints_plot} points{weights_print}{bandwidth_print}{kernel_print}{grid_print}{binning_print}",
            fontsize=10,
        )
        plt.plot(x, prob, label=f"KDE")
        plt.plot(x, prob_true, label="true PDF")
        data_np = zfit.run(data)
        plt.hist(data_np,
                 bins=40,
                 density=True,
                 alpha=0.3,
                 label="Kernel points")
        plt.legend()

    abs_tol = 0.005 if kdetype[1] > 3000 else 0.03
    tolfac = 6 if not cfg["type"] == tfp.distributions.Normal else 1
    if cfg.get("binning_method") == "simple":
        tolfac *= 6
    assert zfit.run(integral) == pytest.approx(expected_integral,
                                               abs=abs_tol * tolfac)
    assert tuple(sample.shape) == (1, 1)
    assert tuple(sample2.shape) == (1500, 1)
    assert prob.shape.rank == 1
    assert prob.shape[0] == x.shape[0]
    assert np.mean(prob - prob_true) < 0.07 * tolfac
    # make sure that on average, most values are close
    assert np.mean(
        (prob /
         prob_true)[prob_true > np.mean(prob_true)]**2) == pytest.approx(
             1, abs=0.1 * tolfac)
    rtol = 0.05
    np.testing.assert_allclose(prob, prob_true, rtol=rtol, atol=0.01 * tolfac)