コード例 #1
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def test_urls(axes, test_GridQubit):
    row_col_list = ((0, 5), (8, 1), (7, 0), (13, 5), (1, 6), (3, 2), (2, 8))
    if test_GridQubit:
        qubits = [grid_qubit.GridQubit(*row_col) for row_col in row_col_list]
    else:
        qubits = row_col_list
    values = np.random.random(len(qubits))
    test_value_map = {qubit: value for qubit, value in zip(qubits, values)}
    test_url_map = {
        qubit: 'http://google.com/{}+{}'.format(*row_col)
        for qubit, row_col in zip(qubits, row_col_list)
        if row_col != (1, 6)
    }
    # Add an extra entry that should not show up in results because the
    # qubit is not in the value map.
    extra_qubit = grid_qubit.GridQubit(10, 7) if test_GridQubit else (10, 7)
    test_url_map[extra_qubit] = 'http://google.com/10+7'

    my_heatmap = heatmap.Heatmap(test_value_map).set_url_map(test_url_map)
    mesh, _ = my_heatmap.plot(axes)
    expected_urls = [
        test_url_map.get(qubit, '')
        for row_col, qubit in sorted(zip(row_col_list, qubits))
    ]
    assert mesh.get_urls() == expected_urls
コード例 #2
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def test_invalid_args():
    value_map = {
        (grid_qubit.GridQubit(3, 2), grid_qubit.GridQubit(4, 2)):
        0.004619111460557768,
        (grid_qubit.GridQubit(4, 1), grid_qubit.GridQubit(4, 2)):
        0.0076079162393482835,
    }
    with pytest.raises(ValueError, match="invalid argument.*colormap"):
        heatmap.TwoQubitInteractionHeatmap(value_map, colormap='Greys')
コード例 #3
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def test_two_qubit_nearest_neighbor(ax):
    value_map = {
        (grid_qubit.GridQubit(3, 2), grid_qubit.GridQubit(4, 2)):
        0.004619111460557768,
        (grid_qubit.GridQubit(4, 1), grid_qubit.GridQubit(3, 2)):
        0.0076079162393482835,
    }
    with pytest.raises(ValueError, match="not nearest neighbors"):
        heatmap.TwoQubitInteractionHeatmap(value_map, coupler_width=0).plot(ax)
コード例 #4
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def test_two_qubit_heatmap(ax):
    value_map = {
        (grid_qubit.GridQubit(3, 2), grid_qubit.GridQubit(4, 2)):
        0.004619111460557768,
        (grid_qubit.GridQubit(4, 1), grid_qubit.GridQubit(4, 2)):
        0.0076079162393482835,
    }
    title = "Two Qubit Interaction Heatmap"
    heatmap.TwoQubitInteractionHeatmap(value_map, title=title).plot(ax)
    assert ax.get_title() == title
コード例 #5
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def test_annotation_map(axes, test_GridQubit):
    row_col_list = [(0, 5), (8, 1), (7, 0), (13, 5), (1, 6), (3, 2), (2, 8)]
    if test_GridQubit:
        qubits = [grid_qubit.GridQubit(*row_col) for row_col in row_col_list]
    else:
        qubits = row_col_list
    values = np.random.random(len(qubits))
    annos = np.random.choice([c for c in string.ascii_letters], len(qubits))
    test_value_map = {qubit: value for qubit, value in zip(qubits, values)}
    test_anno_map = {
        qubit: anno
        for qubit, row_col, anno in zip(qubits, row_col_list, annos)
        if row_col != (1, 6)
    }
    random_heatmap = (
        heatmap.Heatmap(test_value_map).set_annotation_map(test_anno_map))
    random_heatmap.plot(axes)
    actual_texts = set()
    for artist in axes.get_children():
        if isinstance(artist, mpl.text.Text):
            col, row = artist.get_position()
            assert (row, col) != (1, 6)
            actual_texts.add(((row, col), artist.get_text()))
    expected_texts = set((row_col, anno)
                         for row_col, anno in zip(row_col_list, annos)
                         if row_col != (1, 6))
    assert expected_texts.issubset(actual_texts)
コード例 #6
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def test_cell_colors(ax, colormap_name):
    row_col_list = ((0, 5), (8, 1), (7, 0), (13, 5), (1, 6), (3, 2), (2, 8))
    qubits = [grid_qubit.GridQubit(row, col) for (row, col) in row_col_list]
    values = 1.0 + 2.0 * np.random.random(len(qubits))  # [1, 3)
    test_value_map = {(qubit, ): value for qubit, value in zip(qubits, values)}
    test_row_col_map = {rc: value for rc, value in zip(row_col_list, values)}
    vmin, vmax = 1.5, 2.5
    random_heatmap = heatmap.Heatmap(
        test_value_map,
        collection_options={'cmap': colormap_name},
        vmin=vmin,
        vmax=vmax)
    _, mesh = random_heatmap.plot(ax)

    colormap = mpl.cm.get_cmap(colormap_name)
    for path, facecolor in zip(mesh.get_paths(), mesh.get_facecolors()):
        vertices = path.vertices[0:4]
        row = int(round(np.mean([v[1] for v in vertices])))
        col = int(round(np.mean([v[0] for v in vertices])))
        value = test_row_col_map[(row, col)]
        color_scale = (value - vmin) / (vmax - vmin)
        if color_scale < 0.0:
            color_scale = 0.0
        if color_scale > 1.0:
            color_scale = 1.0
        expected_color = np.array(colormap(color_scale))
        assert np.all(np.isclose(facecolor, expected_color))
コード例 #7
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def test_non_float_values(ax, format_string):
    class Foo:
        def __init__(self, value: float, unit: str):
            self.value = value
            self.unit = unit

        def __float__(self):
            return self.value

        def __format__(self, format_string):
            if format_string == 's':
                return f'{self.value}{self.unit}'
            else:
                return format(self.value, format_string)

    row_col_list = ((0, 5), (8, 1), (7, 0), (13, 5), (1, 6), (3, 2), (2, 8))
    qubits = [grid_qubit.GridQubit(row, col) for (row, col) in row_col_list]
    values = np.random.random(len(qubits))
    units = np.random.choice([c for c in string.ascii_letters], len(qubits))
    test_value_map = {(qubit, ): Foo(float(value), unit)
                      for qubit, value, unit in zip(qubits, values, units)}
    row_col_map = {
        row_col: Foo(float(value), unit)
        for row_col, value, unit in zip(row_col_list, values, units)
    }
    colormap_name = 'viridis'
    vmin, vmax = 0.0, 1.0
    random_heatmap = heatmap.Heatmap(
        test_value_map,
        collection_options={'cmap': colormap_name},
        vmin=vmin,
        vmax=vmax,
        annotation_format=format_string,
    )

    _, mesh = random_heatmap.plot(ax)

    colormap = mpl.cm.get_cmap(colormap_name)
    for path, facecolor in zip(mesh.get_paths(), mesh.get_facecolors()):
        vertices = path.vertices[0:4]
        row = int(round(np.mean([v[1] for v in vertices])))
        col = int(round(np.mean([v[0] for v in vertices])))
        foo = row_col_map[(row, col)]
        color_scale = (foo.value - vmin) / (vmax - vmin)
        expected_color = np.array(colormap(color_scale))
        assert np.all(np.isclose(facecolor, expected_color))

    for artist in ax.get_children():
        if isinstance(artist, mpl.text.Text):
            col, row = artist.get_position()
            if (row, col) in test_value_map:
                foo = test_value_map[(row, col)]
                actual_text = artist.get_text()
                expected_text = format(foo, format_string)
                assert actual_text == expected_text
コード例 #8
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ファイル: heatmap_test.py プロジェクト: btribit/Cirq
def test_cells_positions(ax):
    row_col_list = ((0, 5), (8, 1), (7, 0), (13, 5), (1, 6), (3, 2), (2, 8))
    qubits = [grid_qubit.GridQubit(row, col) for (row, col) in row_col_list]
    values = np.random.random(len(qubits))
    test_value_map = {(qubit, ): value for qubit, value in zip(qubits, values)}
    _, collection = heatmap.Heatmap(test_value_map).plot(ax)

    found_qubits = set()
    for path in collection.get_paths():
        vertices = path.vertices[0:4]
        row = int(round(np.mean([v[1] for v in vertices])))
        col = int(round(np.mean([v[0] for v in vertices])))
        found_qubits.add((row, col))
    assert found_qubits == set(row_col_list)
コード例 #9
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def test_colorbar(ax, position, size, pad):
    row_col_list = ((0, 5), (8, 1), (7, 0), (13, 5), (1, 6), (3, 2), (2, 8))
    qubits = [grid_qubit.GridQubit(row, col) for (row, col) in row_col_list]
    values = np.random.random(len(qubits))
    test_value_map = {(qubit, ): value for qubit, value in zip(qubits, values)}
    random_heatmap = heatmap.Heatmap(test_value_map, plot_colorbar=False)
    fig1, ax1 = plt.subplots()
    random_heatmap.plot(ax1)
    fig2, ax2 = plt.subplots()
    random_heatmap.plot(ax2,
                        plot_colorbar=True,
                        colorbar_position=position,
                        colorbar_size=size,
                        colorbar_pad=pad)

    # We need to call savefig() explicitly for updating axes position since the figure
    # object has been altered in the HeatMap._plot_colorbar function.
    tmp_dir = mkdtemp()
    fig2.savefig(pathlib.Path(tmp_dir) / 'tmp.png')

    # Check that the figure has one more object in it when colorbar is on.
    assert len(fig2.get_children()) == len(fig1.get_children()) + 1

    fig_pos = fig2.get_axes()[0].get_position()
    colorbar_pos = fig2.get_axes()[1].get_position()

    origin_axes_size = (fig_pos.xmax - fig_pos.xmin if position
                        in ["left", "right"] else fig_pos.ymax - fig_pos.ymin)
    expected_pad = int(pad.replace("%", "")) / 100 * origin_axes_size
    expected_size = int(size.replace("%", "")) / 100 * origin_axes_size

    if position == "right":
        pad_distance = colorbar_pos.xmin - fig_pos.xmax
        colorbar_size = colorbar_pos.xmax - colorbar_pos.xmin
    elif position == "left":
        pad_distance = fig_pos.xmin - colorbar_pos.xmax
        colorbar_size = colorbar_pos.xmax - colorbar_pos.xmin
    elif position == "top":
        pad_distance = colorbar_pos.ymin - fig_pos.ymax
        colorbar_size = colorbar_pos.ymax - colorbar_pos.ymin
    elif position == "bottom":
        pad_distance = fig_pos.ymin - colorbar_pos.ymax
        colorbar_size = colorbar_pos.ymax - colorbar_pos.ymin

    assert np.isclose(colorbar_size, expected_size)
    assert np.isclose(pad_distance, expected_pad)

    plt.close(fig1)
    plt.close(fig2)
コード例 #10
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def test_annotation_position_and_content(ax, format_string):
    row_col_list = ((0, 5), (8, 1), (7, 0), (13, 5), (1, 6), (3, 2), (2, 8))
    qubits = [grid_qubit.GridQubit(row, col) for (row, col) in row_col_list]
    values = np.random.random(len(qubits))
    test_value_map = {(qubit, ): value for qubit, value in zip(qubits, values)}
    test_row_col_map = {rc: value for rc, value in zip(row_col_list, values)}
    random_heatmap = heatmap.Heatmap(test_value_map,
                                     annotation_format=format_string)
    random_heatmap.plot(ax)
    actual_texts = set()
    for artist in ax.get_children():
        if isinstance(artist, mpl.text.Text):
            col, row = artist.get_position()
            text = artist.get_text()
            actual_texts.add(((row, col), text))
    expected_texts = set((qubit, format(value, format_string))
                         for qubit, value in test_row_col_map.items())
    assert expected_texts.issubset(actual_texts)
コード例 #11
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def test_default_annotation(ax):
    """Tests that the default annotation is '.2g' format on float(value)."""
    row_col_list = ((0, 5), (8, 1), (7, 0), (13, 5), (1, 6), (3, 2), (2, 8))
    qubits = [grid_qubit.GridQubit(row, col) for (row, col) in row_col_list]
    values = ['3.752', '42', '-5.27e8', '-7.34e-9', 732, 0.432, 3.9753e28]
    test_value_map = {(qubit, ): value for qubit, value in zip(qubits, values)}
    test_row_col_map = {rc: value for rc, value in zip(row_col_list, values)}
    random_heatmap = heatmap.Heatmap(test_value_map)
    random_heatmap.plot(ax)
    actual_texts = set()
    for artist in ax.get_children():
        if isinstance(artist, mpl.text.Text):
            col, row = artist.get_position()
            text = artist.get_text()
            actual_texts.add(((row, col), text))
    expected_texts = set((qubit, format(float(value), '.2g'))
                         for qubit, value in test_row_col_map.items())
    assert expected_texts.issubset(actual_texts)
コード例 #12
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def test_plot_updates_local_config():
    value_map_2d = {
        (grid_qubit.GridQubit(3, 2), grid_qubit.GridQubit(4, 2)):
        0.004619111460557768,
        (grid_qubit.GridQubit(4, 1), grid_qubit.GridQubit(4, 2)):
        0.0076079162393482835,
    }
    value_map_1d = {
        (grid_qubit.GridQubit(3, 2), ): 0.004619111460557768,
        (grid_qubit.GridQubit(4, 2), ): 0.0076079162393482835,
    }
    original_title = "Two Qubit Interaction Heatmap"
    new_title = "Temporary title for the plot"
    for random_heatmap in [
            heatmap.TwoQubitInteractionHeatmap(value_map_2d,
                                               title=original_title),
            heatmap.Heatmap(value_map_1d, title=original_title),
    ]:
        _, ax = plt.subplots()
        random_heatmap.plot(ax, title=new_title)
        assert ax.get_title() == new_title
        _, ax = plt.subplots()
        random_heatmap.plot(ax)
        assert ax.get_title() == original_title