Exemple #1
0
def test_modes_grid(ell_max, eps):
    ell_max = max(3, ell_max)
    np.random.seed(1234)
    wigner = sf.Wigner(ell_max)
    ϵ = 10 * (2 * ell_max + 1) * eps
    n_theta = n_phi = 2 * ell_max + 1

    rotors = quaternionic.array.from_spherical_coordinates(
        sf.theta_phi(n_theta, n_phi))

    for s in range(-2, 2 + 1):
        ell_min = abs(s)
        a1 = np.random.rand(11, sf.Ysize(ell_min, ell_max) * 2).view(complex)
        m1 = sf.Modes(a1, spin_weight=s, ell_min=ell_min, ell_max=ell_max)

        f1 = m1.grid(n_theta, n_phi)
        assert f1.shape == m1.shape[:-1] + rotors.shape[:-1]

        sYlm = np.zeros((sf.Ysize(0, ell_max), ) + rotors.shape[:-1],
                        dtype=complex)
        for i, Rs in enumerate(rotors):
            for j, R in enumerate(Rs):
                wigner.sYlm(s, R, out=sYlm[:, i, j])
        f2 = np.tensordot(m1.view(np.ndarray), sYlm, axes=([-1], [0]))
        assert f2.shape == m1.shape[:-1] + rotors.shape[:-1]

        assert np.allclose(
            f1.ndarray, f2, rtol=ϵ,
            atol=ϵ), f"max|f1-f2|={np.max(np.abs(f1.ndarray-f2))} > ϵ={ϵ}"
Exemple #2
0
def test_wigner_evaluate(horner, ell_max_slow, eps):
    import time

    ell_max = max(3, ell_max_slow)
    np.random.seed(1234)
    ϵ = 10 * (2 * ell_max + 1) * eps
    n_theta = n_phi = 2 * ell_max + 1
    max_s = 2
    wigner = sf.Wigner(ell_max, mp_max=max_s)

    max_error = 0.0
    total_time = 0.0
    for rotors in [
            quaternionic.array.from_spherical_coordinates(
                sf.theta_phi(n_theta, n_phi)),
            quaternionic.array(np.random.rand(n_theta, n_phi, 4)).normalized
    ]:

        for s in range(-max_s, max_s + 1):
            ell_min = abs(s)

            a1 = np.random.rand(7,
                                sf.Ysize(ell_min, ell_max) * 2).view(complex)
            a1[:,
               sf.Yindex(ell_min, -ell_min, ell_min):sf.
               Yindex(abs(s), -abs(s), ell_min)] = 0.0

            m1 = sf.Modes(a1, spin_weight=s, ell_min=ell_min, ell_max=ell_max)

            t1 = time.perf_counter()
            f1 = wigner.evaluate(m1, rotors, horner=horner)
            t2 = time.perf_counter()
            assert f1.shape == m1.shape[:-1] + rotors.shape[:-1]
            # print(f"Evaluation for s={s} took {t2-t1:.4f} seconds")
            # print(f1.shape)

            sYlm = np.zeros((sf.Ysize(0, ell_max), ) + rotors.shape[:-1],
                            dtype=complex)
            for i, Rs in enumerate(rotors):
                for j, R in enumerate(Rs):
                    wigner.sYlm(s, R, out=sYlm[:, i, j])
            f2 = np.tensordot(m1.view(np.ndarray), sYlm, axes=([-1], [0]))
            assert f2.shape == m1.shape[:-1] + rotors.shape[:-1]

            assert np.allclose(f1, f2, rtol=ϵ, atol=ϵ), (
                f"max|f1-f2|={np.max(np.abs(f1-f2))} > ϵ={ϵ}\n\n"
                f"s = {s}\n\nrotors = {rotors.tolist()}\n\n"
                # f"f1 = {f1.tolist()}\n\nf2 = {f2.tolist()}"
            )

            max_error = max(np.max(np.abs(f1 - f2)), max_error)
            total_time += t2 - t1

    print()
    print(f"\tmax_error[{horner}] = {max_error}")
    print(f"\ttotal_time[{horner}] = {total_time}")
Exemple #3
0
def test_Ysize(ell_max):
    # k = 0
    for ell_max in range(ell_max + 1):
        for ell_min in range(ell_max + 1):
            a = sf.Ysize(ell_min, ell_max)
            b = len(sf.Yrange(ell_min, ell_max))
            assert a == b, ((ell_min, ell_max), a, b)  #, k)
Exemple #4
0
def test_wigner_rotate_composition(horner, Rs, ell_max_slow, eps):
    import time
    ell_min = 0
    ell_max = max(3, ell_max_slow)
    np.random.seed(1234)
    ϵ = (10 * (2 * ell_max + 1))**2 * eps
    wigner = sf.Wigner(ell_max)
    skipping = 5

    print()
    max_error = 0.0
    total_time = 0.0
    Rs = Rs[::skipping]
    for i, R1 in enumerate(Rs):
        # print(f"\tR1[{i+1}] of {len(Rs)}")
        for j, R2 in enumerate(Rs):
            for spin_weight in range(-2, 2 + 1):
                a1 = np.random.rand(7,
                                    sf.Ysize(ell_min, ell_max) *
                                    2).view(complex)
                a1[:,
                   sf.Yindex(ell_min, -ell_min, ell_min):sf.
                   Yindex(abs(spin_weight), -abs(spin_weight), ell_min)] = 0.0
                m1 = sf.Modes(a1,
                              spin_weight=spin_weight,
                              ell_min=ell_min,
                              ell_max=ell_max)

                t1 = time.perf_counter()
                fA = wigner.rotate(wigner.rotate(m1, R1, horner=horner),
                                   R2,
                                   horner=horner)
                fB = wigner.rotate(m1, R1 * R2, horner=horner)
                t2 = time.perf_counter()

                max_error = max(np.max(np.abs(fA - fB)), max_error)
                total_time += t2 - t1

                # import warnings
                # warnings.warn("Eliminating assert for debugging")
                assert np.allclose(
                    fA, fB, rtol=ϵ, atol=ϵ
                ), f"{np.max(np.abs(fA-fB))} > {ϵ} for R1={R1} R2={R2}"

    print(f"\tmax_error[{horner}] = {max_error}")
    print(f"\ttotal_time[{horner}] = {total_time}")
Exemple #5
0
def test_wigner_evaluate_vs_spinsfast(horner, ell_max, eps):
    import time

    ell_max = max(3, ell_max)
    np.random.seed(1234)
    ϵ = ell_max * (2 * ell_max + 1) * eps
    n_theta = n_phi = 2 * ell_max + 1
    max_s = 2
    wigner = sf.Wigner(ell_max, mp_max=max_s)

    rotors = quaternionic.array.from_spherical_coordinates(
        sf.theta_phi(n_theta, n_phi))

    max_error = 0.0
    total_time = 0.0
    for s in range(-max_s, max_s + 1):
        ell_min = abs(s)

        a1 = np.random.rand(7, sf.Ysize(ell_min, ell_max) * 2).view(complex)
        m1 = sf.Modes(a1, spin_weight=s, ell_min=ell_min, ell_max=ell_max)

        t1 = time.perf_counter()
        f1 = wigner.evaluate(m1, rotors, horner=horner)
        t2 = time.perf_counter()
        assert f1.shape == m1.shape[:-1] + rotors.shape[:-1]

        f2 = m1.grid(n_theta, n_phi, use_spinsfast=True)
        assert f2.shape == m1.shape[:-1] + rotors.shape[:-1]

        assert np.allclose(f1, f2.ndarray, rtol=ϵ, atol=ϵ), (
            f"max|f1-f2|={np.max(np.abs(f1-f2.ndarray))} > ϵ={ϵ}\n\n"
            f"s = {s}\n\nrotors = {rotors.tolist()}\n\n"
            # f"f1 = {f1.tolist()}\n\nf2 = {f2.tolist()}"
        )

        max_error = max(np.max(np.abs(f1 - f2.ndarray)), max_error)
        total_time += t2 - t1

    print()
    print(f"\tmax_error[{horner}] = {max_error}")
    print(f"\ttotal_time[{horner}] = {total_time}")
Exemple #6
0
def test_modes_grid_variants(ell_max, eps):
    ell_max = max(3, ell_max)
    s_max = 2
    np.random.seed(1234)
    ϵ = 10 * (2 * ell_max + 1) * eps
    n_theta = n_phi = 2 * ell_max + 1

    rotors = quaternionic.array.from_spherical_coordinates(
        sf.theta_phi(n_theta, n_phi))

    for s in range(-s_max, s_max + 1):
        ell_min = abs(s)
        a1 = np.random.rand(2, sf.Ysize(ell_min, ell_max) * 2).view(complex)
        m1 = sf.Modes(a1, spin_weight=s, ell_min=ell_min, ell_max=ell_max)

        fA = m1.grid(n_theta, n_phi, use_spinsfast=True)
        fB = m1.grid(n_theta, n_phi, use_spinsfast=False)
        assert np.allclose(fA.ndarray, fB.ndarray, rtol=ϵ, atol=ϵ), (
            f"fA = np.array({fA.ndarray.tolist()})\n\n"
            f"fB = np.array({fB.ndarray.tolist()})\n\n"
            "\n"
            f"max|fA-fB|={np.max(np.abs(fA.ndarray-fB.ndarray))} > ϵ={ϵ}; s={s}"
        )