from contextlib import nullcontext from datetime import datetime import io from pathlib import Path import platform from types import SimpleNamespace import warnings import matplotlib as mpl from matplotlib import cbook, rcParams from matplotlib.testing.decorators import image_comparison, check_figures_equal from matplotlib.axes import Axes from matplotlib.figure import Figure from matplotlib.ticker import AutoMinorLocator, FixedFormatter, ScalarFormatter import matplotlib.pyplot as plt import matplotlib.dates as mdates import matplotlib.gridspec as gridspec from matplotlib.cbook import MatplotlibDeprecationWarning import numpy as np import pytest @image_comparison(['figure_align_labels'], extensions=['png', 'svg'], tol=0 if platform.machine() == 'x86_64' else 0.01) def test_align_labels(): fig = plt.figure(tight_layout=True) gs = gridspec.GridSpec(3, 3) ax = fig.add_subplot(gs[0, :2]) ax.plot(np.arange(0, 1e6, 1000)) ax.set_ylabel('Ylabel0 0') ax = fig.add_subplot(gs[0, -1]) ax.plot(np.arange(0, 1e4, 100)) for i in range(3): ax = fig.add_subplot(gs[1, i]) ax.set_ylabel('YLabel1 %d' % i) ax.set_xlabel('XLabel1 %d' % i) if i in [0, 2]: ax.xaxis.set_label_position("top") ax.xaxis.tick_top() if i == 0: for tick in ax.get_xticklabels(): tick.set_rotation(90) if i == 2: ax.yaxis.set_label_position("right") ax.yaxis.tick_right() for i in range(3): ax = fig.add_subplot(gs[2, i]) ax.set_xlabel(f'XLabel2 {i}') ax.set_ylabel(f'YLabel2 {i}') if i == 2: ax.plot(np.arange(0, 1e4, 10)) ax.yaxis.set_label_position("right") ax.yaxis.tick_right() for tick in ax.get_xticklabels(): tick.set_rotation(90) fig.align_labels() def test_figure_label(): # pyplot figure creation, selection, and closing with label/number/instance plt.close('all') fig_today = plt.figure('today') plt.figure(3) plt.figure('tomorrow') plt.figure() plt.figure(0) plt.figure(1) plt.figure(3) assert plt.get_fignums() == [0, 1, 3, 4, 5] assert plt.get_figlabels() == ['', 'today', '', 'tomorrow', ''] plt.close(10) plt.close() plt.close(5) plt.close('tomorrow') assert plt.get_fignums() == [0, 1] assert plt.get_figlabels() == ['', 'today'] plt.figure(fig_today) assert plt.gcf() == fig_today with pytest.raises(ValueError): plt.figure(Figure()) def test_fignum_exists(): # pyplot figure creation, selection and closing with fignum_exists plt.figure('one') plt.figure(2) plt.figure('three') plt.figure() assert plt.fignum_exists('one') assert plt.fignum_exists(2) assert plt.fignum_exists('three') assert plt.fignum_exists(4) plt.close('one') plt.close(4) assert not plt.fignum_exists('one') assert not plt.fignum_exists(4) def test_clf_keyword(): # test if existing figure is cleared with figure() and subplots() text1 = 'A fancy plot' text2 = 'Really fancy!' fig0 = plt.figure(num=1) fig0.suptitle(text1) assert [t.get_text() for t in fig0.texts] == [text1] fig1 = plt.figure(num=1, clear=False) fig1.text(0.5, 0.5, text2) assert fig0 is fig1 assert [t.get_text() for t in fig1.texts] == [text1, text2] fig2, ax2 = plt.subplots(2, 1, num=1, clear=True) assert fig0 is fig2 assert [t.get_text() for t in fig2.texts] == [] @image_comparison(['figure_today']) def test_figure(): # named figure support fig = plt.figure('today') ax = fig.add_subplot() ax.set_title(fig.get_label()) ax.plot(np.arange(5)) # plot red line in a different figure. plt.figure('tomorrow') plt.plot([0, 1], [1, 0], 'r') # Return to the original; make sure the red line is not there. plt.figure('today') plt.close('tomorrow') @image_comparison(['figure_legend']) def test_figure_legend(): fig, axs = plt.subplots(2) axs[0].plot([0, 1], [1, 0], label='x', color='g') axs[0].plot([0, 1], [0, 1], label='y', color='r') axs[0].plot([0, 1], [0.5, 0.5], label='y', color='k') axs[1].plot([0, 1], [1, 0], label='_y', color='r') axs[1].plot([0, 1], [0, 1], label='z', color='b') fig.legend() def test_gca(): fig = plt.figure() with pytest.warns(UserWarning): # empty call to add_axes() will throw deprecation warning assert fig.add_axes() is None ax0 = fig.add_axes([0, 0, 1, 1]) with pytest.warns( MatplotlibDeprecationWarning, match=r'Calling gca\(\) with keyword arguments was deprecated'): assert fig.gca(projection='rectilinear') is ax0 assert fig.gca() is ax0 ax1 = fig.add_axes(rect=[0.1, 0.1, 0.8, 0.8]) with pytest.warns( MatplotlibDeprecationWarning, match=r'Calling gca\(\) with keyword arguments was deprecated'): assert fig.gca(projection='rectilinear') is ax1 assert fig.gca() is ax1 ax2 = fig.add_subplot(121, projection='polar') assert fig.gca() is ax2 with pytest.warns( MatplotlibDeprecationWarning, match=r'Calling gca\(\) with keyword arguments was deprecated'): assert fig.gca(polar=True) is ax2 ax3 = fig.add_subplot(122) assert fig.gca() is ax3 with pytest.warns( MatplotlibDeprecationWarning, match=r'Calling gca\(\) with keyword arguments was deprecated'): assert fig.gca(polar=True) is ax3 with pytest.warns( MatplotlibDeprecationWarning, match=r'Calling gca\(\) with keyword arguments was deprecated'): assert fig.gca(polar=True) is not ax2 assert fig.gca().get_subplotspec().get_geometry() == (1, 2, 1, 1) # add_axes on an existing Axes should not change stored order, but will # make it current. fig.add_axes(ax0) assert fig.axes == [ax0, ax1, ax2, ax3] assert fig.gca() is ax0 # add_subplot on an existing Axes should not change stored order, but will # make it current. fig.add_subplot(ax2) assert fig.axes == [ax0, ax1, ax2, ax3] assert fig.gca() is ax2 fig.sca(ax1) with pytest.warns( MatplotlibDeprecationWarning, match=r'Calling gca\(\) with keyword arguments was deprecated'): assert fig.gca(projection='rectilinear') is ax1 assert fig.gca() is ax1 # sca() should not change stored order of Axes, which is order added. assert fig.axes == [ax0, ax1, ax2, ax3] def test_add_subplot_subclass(): fig = plt.figure() fig.add_subplot(axes_class=Axes) with pytest.raises(ValueError): fig.add_subplot(axes_class=Axes, projection="3d") with pytest.raises(ValueError): fig.add_subplot(axes_class=Axes, polar=True) with pytest.raises(ValueError): fig.add_subplot(projection="3d", polar=True) with pytest.raises(TypeError): fig.add_subplot(projection=42) def test_add_subplot_invalid(): fig = plt.figure() with pytest.raises(ValueError, match='Number of columns must be a positive integer'): fig.add_subplot(2, 0, 1) with pytest.raises(ValueError, match='Number of rows must be a positive integer'): fig.add_subplot(0, 2, 1) with pytest.raises(ValueError, match='num must be 1 <= num <= 4'): fig.add_subplot(2, 2, 0) with pytest.raises(ValueError, match='num must be 1 <= num <= 4'): fig.add_subplot(2, 2, 5) with pytest.raises(ValueError, match='must be a three-digit integer'): fig.add_subplot(42) with pytest.raises(ValueError, match='must be a three-digit integer'): fig.add_subplot(1000) with pytest.raises(TypeError, match='takes 1 or 3 positional arguments ' 'but 2 were given'): fig.add_subplot(2, 2) with pytest.raises(TypeError, match='takes 1 or 3 positional arguments ' 'but 4 were given'): fig.add_subplot(1, 2, 3, 4) with pytest.warns(cbook.MatplotlibDeprecationWarning, match='Passing non-integers as three-element position ' 'specification is deprecated'): fig.add_subplot('2', 2, 1) with pytest.warns(cbook.MatplotlibDeprecationWarning, match='Passing non-integers as three-element position ' 'specification is deprecated'): fig.add_subplot(2.0, 2, 1) _, ax = plt.subplots() with pytest.raises(ValueError, match='The Subplot must have been created in the ' 'present figure'): fig.add_subplot(ax) @image_comparison(['figure_suptitle']) def test_suptitle(): fig, _ = plt.subplots() fig.suptitle('hello', color='r') fig.suptitle('title', color='g', rotation='30') def test_suptitle_fontproperties(): fig, ax = plt.subplots() fps = mpl.font_manager.FontProperties(size='large', weight='bold') txt = fig.suptitle('fontprops title', fontproperties=fps) assert txt.get_fontsize() == fps.get_size_in_points() assert txt.get_weight() == fps.get_weight() @image_comparison(['alpha_background'], # only test png and svg. The PDF output appears correct, # but Ghostscript does not preserve the background color. extensions=['png', 'svg'], savefig_kwarg={'facecolor': (0, 1, 0.4), 'edgecolor': 'none'}) def test_alpha(): # We want an image which has a background color and an alpha of 0.4. fig = plt.figure(figsize=[2, 1]) fig.set_facecolor((0, 1, 0.4)) fig.patch.set_alpha(0.4) fig.patches.append(mpl.patches.CirclePolygon( [20, 20], radius=15, alpha=0.6, facecolor='red')) def test_too_many_figures(): with pytest.warns(RuntimeWarning): for i in range(rcParams['figure.max_open_warning'] + 1): plt.figure() def test_iterability_axes_argument(): # This is a regression test for matplotlib/matplotlib#3196. If one of the # arguments returned by _as_mpl_axes defines __getitem__ but is not # iterable, this would raise an exception. This is because we check # whether the arguments are iterable, and if so we try and convert them # to a tuple. However, the ``iterable`` function returns True if # __getitem__ is present, but some classes can define __getitem__ without # being iterable. The tuple conversion is now done in a try...except in # case it fails. class MyAxes(Axes): def __init__(self, *args, myclass=None, **kwargs): return Axes.__init__(self, *args, **kwargs) class MyClass: def __getitem__(self, item): if item != 'a': raise ValueError("item should be a") def _as_mpl_axes(self): return MyAxes, {'myclass': self} fig = plt.figure() fig.add_subplot(1, 1, 1, projection=MyClass()) plt.close(fig) def test_set_fig_size(): fig = plt.figure() # check figwidth fig.set_figwidth(5) assert fig.get_figwidth() == 5 # check figheight fig.set_figheight(1) assert fig.get_figheight() == 1 # check using set_size_inches fig.set_size_inches(2, 4) assert fig.get_figwidth() == 2 assert fig.get_figheight() == 4 # check using tuple to first argument fig.set_size_inches((1, 3)) assert fig.get_figwidth() == 1 assert fig.get_figheight() == 3 def test_axes_remove(): fig, axs = plt.subplots(2, 2) axs[-1, -1].remove() for ax in axs.ravel()[:-1]: assert ax in fig.axes assert axs[-1, -1] not in fig.axes assert len(fig.axes) == 3 def test_figaspect(): w, h = plt.figaspect(np.float64(2) / np.float64(1)) assert h / w == 2 w, h = plt.figaspect(2) assert h / w == 2 w, h = plt.figaspect(np.zeros((1, 2))) assert h / w == 0.5 w, h = plt.figaspect(np.zeros((2, 2))) assert h / w == 1 @pytest.mark.parametrize('which', [None, 'both', 'major', 'minor']) def test_autofmt_xdate(which): date = ['3 Jan 2013', '4 Jan 2013', '5 Jan 2013', '6 Jan 2013', '7 Jan 2013', '8 Jan 2013', '9 Jan 2013', '10 Jan 2013', '11 Jan 2013', '12 Jan 2013', '13 Jan 2013', '14 Jan 2013'] time = ['16:44:00', '16:45:00', '16:46:00', '16:47:00', '16:48:00', '16:49:00', '16:51:00', '16:52:00', '16:53:00', '16:55:00', '16:56:00', '16:57:00'] angle = 60 minors = [1, 2, 3, 4, 5, 6, 7] x = mdates.datestr2num(date) y = mdates.datestr2num(time) fig, ax = plt.subplots() ax.plot(x, y) ax.yaxis_date() ax.xaxis_date() ax.xaxis.set_minor_locator(AutoMinorLocator(2)) with warnings.catch_warnings(): warnings.filterwarnings( 'ignore', 'FixedFormatter should only be used together with FixedLocator') ax.xaxis.set_minor_formatter(FixedFormatter(minors)) with (pytest.warns(mpl.MatplotlibDeprecationWarning) if which is None else nullcontext()): fig.autofmt_xdate(0.2, angle, 'right', which) if which in ('both', 'major', None): for label in fig.axes[0].get_xticklabels(False, 'major'): assert int(label.get_rotation()) == angle if which in ('both', 'minor'): for label in fig.axes[0].get_xticklabels(True, 'minor'): assert int(label.get_rotation()) == angle @pytest.mark.style('default') def test_change_dpi(): fig = plt.figure(figsize=(4, 4)) fig.canvas.draw() assert fig.canvas.renderer.height == 400 assert fig.canvas.renderer.width == 400 fig.dpi = 50 fig.canvas.draw() assert fig.canvas.renderer.height == 200 assert fig.canvas.renderer.width == 200 @pytest.mark.parametrize('width, height', [ (1, np.nan), (-1, 1), (np.inf, 1) ]) def test_invalid_figure_size(width, height): with pytest.raises(ValueError): plt.figure(figsize=(width, height)) fig = plt.figure() with pytest.raises(ValueError): fig.set_size_inches(width, height) def test_invalid_figure_add_axes(): fig = plt.figure() with pytest.raises(ValueError): fig.add_axes((.1, .1, .5, np.nan)) with pytest.raises(TypeError, match="multiple values for argument 'rect'"): fig.add_axes([0, 0, 1, 1], rect=[0, 0, 1, 1]) _, ax = plt.subplots() with pytest.raises(ValueError, match="The Axes must have been created in the present " "figure"): fig.add_axes(ax) def test_subplots_shareax_loglabels(): fig, axs = plt.subplots(2, 2, sharex=True, sharey=True, squeeze=False) for ax in axs.flat: ax.plot([10, 20, 30], [10, 20, 30]) ax.set_yscale("log") ax.set_xscale("log") for ax in axs[0, :]: assert 0 == len(ax.xaxis.get_ticklabels(which='both')) for ax in axs[1, :]: assert 0 < len(ax.xaxis.get_ticklabels(which='both')) for ax in axs[:, 1]: assert 0 == len(ax.yaxis.get_ticklabels(which='both')) for ax in axs[:, 0]: assert 0 < len(ax.yaxis.get_ticklabels(which='both')) def test_savefig(): fig = plt.figure() msg = r"savefig\(\) takes 2 positional arguments but 3 were given" with pytest.raises(TypeError, match=msg): fig.savefig("fname1.png", "fname2.png") def test_savefig_warns(): fig = plt.figure() msg = r'savefig\(\) got unexpected keyword argument "non_existent_kwarg"' for format in ['png', 'pdf', 'svg', 'tif', 'jpg']: with pytest.warns(cbook.MatplotlibDeprecationWarning, match=msg): fig.savefig(io.BytesIO(), format=format, non_existent_kwarg=True) def test_savefig_backend(): fig = plt.figure() # Intentionally use an invalid module name. with pytest.raises(ModuleNotFoundError, match="No module named '@absent'"): fig.savefig("test", backend="module://@absent") with pytest.raises(ValueError, match="The 'pdf' backend does not support png output"): fig.savefig("test.png", backend="pdf") def test_figure_repr(): fig = plt.figure(figsize=(10, 20), dpi=10) assert repr(fig) == "
" def test_warn_cl_plus_tl(): fig, ax = plt.subplots(constrained_layout=True) with pytest.warns(UserWarning): # this should warn, fig.subplots_adjust(top=0.8) assert not(fig.get_constrained_layout()) @check_figures_equal(extensions=["png", "pdf"]) def test_add_artist(fig_test, fig_ref): fig_test.set_dpi(100) fig_ref.set_dpi(100) fig_test.subplots() l1 = plt.Line2D([.2, .7], [.7, .7], gid='l1') l2 = plt.Line2D([.2, .7], [.8, .8], gid='l2') r1 = plt.Circle((20, 20), 100, transform=None, gid='C1') r2 = plt.Circle((.7, .5), .05, gid='C2') r3 = plt.Circle((4.5, .8), .55, transform=fig_test.dpi_scale_trans, facecolor='crimson', gid='C3') for a in [l1, l2, r1, r2, r3]: fig_test.add_artist(a) l2.remove() ax2 = fig_ref.subplots() l1 = plt.Line2D([.2, .7], [.7, .7], transform=fig_ref.transFigure, gid='l1', zorder=21) r1 = plt.Circle((20, 20), 100, transform=None, clip_on=False, zorder=20, gid='C1') r2 = plt.Circle((.7, .5), .05, transform=fig_ref.transFigure, gid='C2', zorder=20) r3 = plt.Circle((4.5, .8), .55, transform=fig_ref.dpi_scale_trans, facecolor='crimson', clip_on=False, zorder=20, gid='C3') for a in [l1, r1, r2, r3]: ax2.add_artist(a) @pytest.mark.parametrize("fmt", ["png", "pdf", "ps", "eps", "svg"]) def test_fspath(fmt, tmpdir): out = Path(tmpdir, "test.{}".format(fmt)) plt.savefig(out) with out.open("rb") as file: # All the supported formats include the format name (case-insensitive) # in the first 100 bytes. assert fmt.encode("ascii") in file.read(100).lower() def test_tightbbox(): fig, ax = plt.subplots() ax.set_xlim(0, 1) t = ax.text(1., 0.5, 'This dangles over end') renderer = fig.canvas.get_renderer() x1Nom0 = 9.035 # inches assert abs(t.get_tightbbox(renderer).x1 - x1Nom0 * fig.dpi) < 2 assert abs(ax.get_tightbbox(renderer).x1 - x1Nom0 * fig.dpi) < 2 assert abs(fig.get_tightbbox(renderer).x1 - x1Nom0) < 0.05 assert abs(fig.get_tightbbox(renderer).x0 - 0.679) < 0.05 # now exclude t from the tight bbox so now the bbox is quite a bit # smaller t.set_in_layout(False) x1Nom = 7.333 assert abs(ax.get_tightbbox(renderer).x1 - x1Nom * fig.dpi) < 2 assert abs(fig.get_tightbbox(renderer).x1 - x1Nom) < 0.05 t.set_in_layout(True) x1Nom = 7.333 assert abs(ax.get_tightbbox(renderer).x1 - x1Nom0 * fig.dpi) < 2 # test bbox_extra_artists method... assert abs(ax.get_tightbbox(renderer, bbox_extra_artists=[]).x1 - x1Nom * fig.dpi) < 2 def test_axes_removal(): # Check that units can set the formatter after an Axes removal fig, axs = plt.subplots(1, 2, sharex=True) axs[1].remove() axs[0].plot([datetime(2000, 1, 1), datetime(2000, 2, 1)], [0, 1]) assert isinstance(axs[0].xaxis.get_major_formatter(), mdates.AutoDateFormatter) # Check that manually setting the formatter, then removing Axes keeps # the set formatter. fig, axs = plt.subplots(1, 2, sharex=True) axs[1].xaxis.set_major_formatter(ScalarFormatter()) axs[1].remove() axs[0].plot([datetime(2000, 1, 1), datetime(2000, 2, 1)], [0, 1]) assert isinstance(axs[0].xaxis.get_major_formatter(), ScalarFormatter) def test_removed_axis(): # Simple smoke test to make sure removing a shared axis works fig, axs = plt.subplots(2, sharex=True) axs[0].remove() fig.canvas.draw() @pytest.mark.style('mpl20') def test_picking_does_not_stale(): fig, ax = plt.subplots() col = ax.scatter([0], [0], [1000], picker=True) fig.canvas.draw() assert not fig.stale mouse_event = SimpleNamespace(x=ax.bbox.x0 + ax.bbox.width / 2, y=ax.bbox.y0 + ax.bbox.height / 2, inaxes=ax, guiEvent=None) fig.pick(mouse_event) assert not fig.stale def test_add_subplot_twotuple(): fig = plt.figure() ax1 = fig.add_subplot(3, 2, (3, 5)) assert ax1.get_subplotspec().rowspan == range(1, 3) assert ax1.get_subplotspec().colspan == range(0, 1) ax2 = fig.add_subplot(3, 2, (4, 6)) assert ax2.get_subplotspec().rowspan == range(1, 3) assert ax2.get_subplotspec().colspan == range(1, 2) ax3 = fig.add_subplot(3, 2, (3, 6)) assert ax3.get_subplotspec().rowspan == range(1, 3) assert ax3.get_subplotspec().colspan == range(0, 2) ax4 = fig.add_subplot(3, 2, (4, 5)) assert ax4.get_subplotspec().rowspan == range(1, 3) assert ax4.get_subplotspec().colspan == range(0, 2) with pytest.raises(IndexError): fig.add_subplot(3, 2, (6, 3)) @image_comparison(['tightbbox_box_aspect.svg'], style='mpl20', savefig_kwarg={'bbox_inches': 'tight', 'facecolor': 'teal'}, remove_text=True) def test_tightbbox_box_aspect(): fig = plt.figure() gs = fig.add_gridspec(1, 2) ax1 = fig.add_subplot(gs[0, 0]) ax2 = fig.add_subplot(gs[0, 1], projection='3d') ax1.set_box_aspect(.5) ax2.set_box_aspect((2, 1, 1)) @check_figures_equal(extensions=["svg", "pdf", "eps", "png"]) def test_animated_with_canvas_change(fig_test, fig_ref): ax_ref = fig_ref.subplots() ax_ref.plot(range(5)) ax_test = fig_test.subplots() ax_test.plot(range(5), animated=True) class TestSubplotMosaic: @check_figures_equal(extensions=["png"]) @pytest.mark.parametrize( "x", [[["A", "A", "B"], ["C", "D", "B"]], [[1, 1, 2], [3, 4, 2]]] ) def test_basic(self, fig_test, fig_ref, x): grid_axes = fig_test.subplot_mosaic(x) for k, ax in grid_axes.items(): ax.set_title(k) labels = sorted(np.unique(x)) assert len(labels) == len(grid_axes) gs = fig_ref.add_gridspec(2, 3) axA = fig_ref.add_subplot(gs[:1, :2]) axA.set_title(labels[0]) axB = fig_ref.add_subplot(gs[:, 2]) axB.set_title(labels[1]) axC = fig_ref.add_subplot(gs[1, 0]) axC.set_title(labels[2]) axD = fig_ref.add_subplot(gs[1, 1]) axD.set_title(labels[3]) @check_figures_equal(extensions=["png"]) def test_all_nested(self, fig_test, fig_ref): x = [["A", "B"], ["C", "D"]] y = [["E", "F"], ["G", "H"]] fig_ref.set_constrained_layout(True) fig_test.set_constrained_layout(True) grid_axes = fig_test.subplot_mosaic([[x, y]]) for ax in grid_axes.values(): ax.set_title(ax.get_label()) gs = fig_ref.add_gridspec(1, 2) gs_left = gs[0, 0].subgridspec(2, 2) for j, r in enumerate(x): for k, label in enumerate(r): fig_ref.add_subplot(gs_left[j, k]).set_title(label) gs_right = gs[0, 1].subgridspec(2, 2) for j, r in enumerate(y): for k, label in enumerate(r): fig_ref.add_subplot(gs_right[j, k]).set_title(label) @check_figures_equal(extensions=["png"]) def test_nested(self, fig_test, fig_ref): fig_ref.set_constrained_layout(True) fig_test.set_constrained_layout(True) x = [["A", "B"], ["C", "D"]] y = [["F"], [x]] grid_axes = fig_test.subplot_mosaic(y) for k, ax in grid_axes.items(): ax.set_title(k) gs = fig_ref.add_gridspec(2, 1) gs_n = gs[1, 0].subgridspec(2, 2) axA = fig_ref.add_subplot(gs_n[0, 0]) axA.set_title("A") axB = fig_ref.add_subplot(gs_n[0, 1]) axB.set_title("B") axC = fig_ref.add_subplot(gs_n[1, 0]) axC.set_title("C") axD = fig_ref.add_subplot(gs_n[1, 1]) axD.set_title("D") axF = fig_ref.add_subplot(gs[0, 0]) axF.set_title("F") @check_figures_equal(extensions=["png"]) def test_nested_tuple(self, fig_test, fig_ref): x = [["A", "B", "B"], ["C", "C", "D"]] xt = (("A", "B", "B"), ("C", "C", "D")) fig_ref.subplot_mosaic([["F"], [x]]) fig_test.subplot_mosaic([["F"], [xt]]) @check_figures_equal(extensions=["png"]) @pytest.mark.parametrize( "x, empty_sentinel", [ ([["A", None], [None, "B"]], None), ([["A", "."], [".", "B"]], "SKIP"), ([["A", 0], [0, "B"]], 0), ([[1, None], [None, 2]], None), ([[1, "."], [".", 2]], "SKIP"), ([[1, 0], [0, 2]], 0), ], ) def test_empty(self, fig_test, fig_ref, x, empty_sentinel): if empty_sentinel != "SKIP": kwargs = {"empty_sentinel": empty_sentinel} else: kwargs = {} grid_axes = fig_test.subplot_mosaic(x, **kwargs) for k, ax in grid_axes.items(): ax.set_title(k) labels = sorted( {name for row in x for name in row} - {empty_sentinel, "."} ) assert len(labels) == len(grid_axes) gs = fig_ref.add_gridspec(2, 2) axA = fig_ref.add_subplot(gs[0, 0]) axA.set_title(labels[0]) axB = fig_ref.add_subplot(gs[1, 1]) axB.set_title(labels[1]) def test_fail_list_of_str(self): with pytest.raises(ValueError, match='must be 2D'): plt.subplot_mosaic(['foo', 'bar']) with pytest.raises(ValueError, match='must be 2D'): plt.subplot_mosaic(['foo']) @check_figures_equal(extensions=["png"]) @pytest.mark.parametrize("subplot_kw", [{}, {"projection": "polar"}, None]) def test_subplot_kw(self, fig_test, fig_ref, subplot_kw): x = [[1, 2]] grid_axes = fig_test.subplot_mosaic(x, subplot_kw=subplot_kw) subplot_kw = subplot_kw or {} gs = fig_ref.add_gridspec(1, 2) axA = fig_ref.add_subplot(gs[0, 0], **subplot_kw) axB = fig_ref.add_subplot(gs[0, 1], **subplot_kw) def test_string_parser(self): normalize = Figure._normalize_grid_string assert normalize('ABC') == [['A', 'B', 'C']] assert normalize('AB;CC') == [['A', 'B'], ['C', 'C']] assert normalize('AB;CC;DE') == [['A', 'B'], ['C', 'C'], ['D', 'E']] assert normalize(""" ABC """) == [['A', 'B', 'C']] assert normalize(""" AB CC """) == [['A', 'B'], ['C', 'C']] assert normalize(""" AB CC DE """) == [['A', 'B'], ['C', 'C'], ['D', 'E']] @check_figures_equal(extensions=["png"]) @pytest.mark.parametrize("str_pattern", ["AAA\nBBB", "\nAAA\nBBB\n", "ABC\nDEF"] ) def test_single_str_input(self, fig_test, fig_ref, str_pattern): grid_axes = fig_test.subplot_mosaic(str_pattern) grid_axes = fig_ref.subplot_mosaic( [list(ln) for ln in str_pattern.strip().split("\n")] ) @pytest.mark.parametrize( "x,match", [ ( [["A", "."], [".", "A"]], ( "(?m)we found that the label .A. specifies a " + "non-rectangular or non-contiguous area." ), ), ( [["A", "B"], [None, [["A", "B"], ["C", "D"]]]], "There are duplicate keys .* between the outer layout", ), ("AAA\nc\nBBB", "All of the rows must be the same length"), ( [["A", [["B", "C"], ["D"]]], ["E", "E"]], "All of the rows must be the same length", ), ], ) def test_fail(self, x, match): fig = plt.figure() with pytest.raises(ValueError, match=match): fig.subplot_mosaic(x) @check_figures_equal(extensions=["png"]) def test_hashable_keys(self, fig_test, fig_ref): fig_test.subplot_mosaic([[object(), object()]]) fig_ref.subplot_mosaic([["A", "B"]]) @pytest.mark.parametrize('str_pattern', ['abc', 'cab', 'bca', 'cba', 'acb', 'bac']) def test_user_order(self, str_pattern): fig = plt.figure() ax_dict = fig.subplot_mosaic(str_pattern) assert list(str_pattern) == list(ax_dict) assert list(fig.axes) == list(ax_dict.values()) def test_nested_user_order(self): layout = [ ["A", [["B", "C"], ["D", "E"]]], ["F", "G"], [".", [["H", [["I"], ["."]]]]] ] fig = plt.figure() ax_dict = fig.subplot_mosaic(layout) assert list(ax_dict) == list("ABCDEFGHI") assert list(fig.axes) == list(ax_dict.values()) def test_reused_gridspec(): """Test that these all use the same gridspec""" fig = plt.figure() ax1 = fig.add_subplot(3, 2, (3, 5)) ax2 = fig.add_subplot(3, 2, 4) ax3 = plt.subplot2grid((3, 2), (2, 1), colspan=2, fig=fig) gs1 = ax1.get_subplotspec().get_gridspec() gs2 = ax2.get_subplotspec().get_gridspec() gs3 = ax3.get_subplotspec().get_gridspec() assert gs1 == gs2 assert gs1 == gs3 @image_comparison(['test_subfigure.png'], style='mpl20', savefig_kwarg={'facecolor': 'teal'}, remove_text=False) def test_subfigure(): np.random.seed(19680801) fig = plt.figure(constrained_layout=True) sub = fig.subfigures(1, 2) axs = sub[0].subplots(2, 2) for ax in axs.flat: pc = ax.pcolormesh(np.random.randn(30, 30), vmin=-2, vmax=2) sub[0].colorbar(pc, ax=axs) sub[0].suptitle('Left Side') axs = sub[1].subplots(1, 3) for ax in axs.flat: pc = ax.pcolormesh(np.random.randn(30, 30), vmin=-2, vmax=2) sub[1].colorbar(pc, ax=axs, location='bottom') sub[1].suptitle('Right Side') fig.suptitle('Figure suptitle', fontsize='xx-large') def test_subfigure_tightbbox(): # test that we can get the tightbbox with a subfigure... fig = plt.figure(constrained_layout=True) sub = fig.subfigures(1, 2) np.testing.assert_allclose( fig.get_tightbbox(fig.canvas.get_renderer()).width, 0.1) @image_comparison(['test_subfigure_ss.png'], style='mpl20', savefig_kwarg={'facecolor': 'teal'}, remove_text=False) def test_subfigure_ss(): # test assigning the subfigure via subplotspec np.random.seed(19680801) fig = plt.figure(constrained_layout=True) gs = fig.add_gridspec(1, 2) sub = fig.add_subfigure(gs[0], facecolor='pink') axs = sub.subplots(2, 2) for ax in axs.flat: pc = ax.pcolormesh(np.random.randn(30, 30), vmin=-2, vmax=2) sub.colorbar(pc, ax=axs) sub.suptitle('Left Side') ax = fig.add_subplot(gs[1]) ax.plot(np.arange(20)) ax.set_title('Axes') fig.suptitle('Figure suptitle', fontsize='xx-large') @image_comparison(['test_subfigure_double.png'], style='mpl20', savefig_kwarg={'facecolor': 'teal'}, remove_text=False) def test_subfigure_double(): # test assigning the subfigure via subplotspec np.random.seed(19680801) fig = plt.figure(constrained_layout=True, figsize=(10, 8)) fig.suptitle('fig') subfigs = fig.subfigures(1, 2, wspace=0.07) subfigs[0].set_facecolor('coral') subfigs[0].suptitle('subfigs[0]') subfigs[1].set_facecolor('coral') subfigs[1].suptitle('subfigs[1]') subfigsnest = subfigs[0].subfigures(2, 1, height_ratios=[1, 1.4]) subfigsnest[0].suptitle('subfigsnest[0]') subfigsnest[0].set_facecolor('r') axsnest0 = subfigsnest[0].subplots(1, 2, sharey=True) for ax in axsnest0: fontsize = 12 pc = ax.pcolormesh(np.random.randn(30, 30), vmin=-2.5, vmax=2.5) ax.set_xlabel('x-label', fontsize=fontsize) ax.set_ylabel('y-label', fontsize=fontsize) ax.set_title('Title', fontsize=fontsize) subfigsnest[0].colorbar(pc, ax=axsnest0) subfigsnest[1].suptitle('subfigsnest[1]') subfigsnest[1].set_facecolor('g') axsnest1 = subfigsnest[1].subplots(3, 1, sharex=True) for nn, ax in enumerate(axsnest1): ax.set_ylabel(f'ylabel{nn}') subfigsnest[1].supxlabel('supxlabel') subfigsnest[1].supylabel('supylabel') axsRight = subfigs[1].subplots(2, 2) def test_subfigure_spanning(): # test that subfigures get laid out properly... fig = plt.figure(constrained_layout=True) gs = fig.add_gridspec(3, 3) sub_figs = [ fig.add_subfigure(gs[0, 0]), fig.add_subfigure(gs[0:2, 1]), fig.add_subfigure(gs[2, 1:3]), ] w = 640 h = 480 np.testing.assert_allclose(sub_figs[0].bbox.min, [0., h * 2/3]) np.testing.assert_allclose(sub_figs[0].bbox.max, [w / 3, h]) np.testing.assert_allclose(sub_figs[1].bbox.min, [w / 3, h / 3]) np.testing.assert_allclose(sub_figs[1].bbox.max, [w * 2/3, h]) np.testing.assert_allclose(sub_figs[2].bbox.min, [w / 3, 0]) np.testing.assert_allclose(sub_figs[2].bbox.max, [w, h / 3]) def test_add_subplot_kwargs(): # fig.add_subplot() always creates new axes, even if axes kwargs differ. fig = plt.figure() ax = fig.add_subplot(1, 1, 1) ax1 = fig.add_subplot(1, 1, 1) assert ax is not None assert ax1 is not ax plt.close() fig = plt.figure() ax = fig.add_subplot(1, 1, 1, projection='polar') ax1 = fig.add_subplot(1, 1, 1, projection='polar') assert ax is not None assert ax1 is not ax plt.close() fig = plt.figure() ax = fig.add_subplot(1, 1, 1, projection='polar') ax1 = fig.add_subplot(1, 1, 1) assert ax is not None assert ax1.name == 'rectilinear' assert ax1 is not ax plt.close() def test_add_axes_kwargs(): # fig.add_axes() always creates new axes, even if axes kwargs differ. fig = plt.figure() ax = fig.add_axes([0, 0, 1, 1]) ax1 = fig.add_axes([0, 0, 1, 1]) assert ax is not None assert ax1 is not ax plt.close() fig = plt.figure() ax = fig.add_axes([0, 0, 1, 1], projection='polar') ax1 = fig.add_axes([0, 0, 1, 1], projection='polar') assert ax is not None assert ax1 is not ax plt.close() fig = plt.figure() ax = fig.add_axes([0, 0, 1, 1], projection='polar') ax1 = fig.add_axes([0, 0, 1, 1]) assert ax is not None assert ax1.name == 'rectilinear' assert ax1 is not ax plt.close()