import difflib import numpy as np import subprocess import sys from pathlib import Path import pytest import matplotlib as mpl from matplotlib import pyplot as plt from matplotlib.cbook import MatplotlibDeprecationWarning def test_pyplot_up_to_date(tmpdir): gen_script = Path(mpl.__file__).parents[2] / "tools/boilerplate.py" if not gen_script.exists(): pytest.skip("boilerplate.py not found") orig_contents = Path(plt.__file__).read_text() plt_file = tmpdir.join('pyplot.py') plt_file.write_text(orig_contents, 'utf-8') subprocess.run([sys.executable, str(gen_script), str(plt_file)], check=True) new_contents = plt_file.read_text('utf-8') if orig_contents != new_contents: diff_msg = '\n'.join( difflib.unified_diff( orig_contents.split('\n'), new_contents.split('\n'), fromfile='found pyplot.py', tofile='expected pyplot.py', n=0, lineterm='')) pytest.fail( "pyplot.py is not up-to-date. Please run " "'python tools/boilerplate.py' to update pyplot.py. " "This needs to be done from an environment where your " "current working copy is installed (e.g. 'pip install -e'd). " "Here is a diff of unexpected differences:\n%s" % diff_msg ) def test_copy_docstring_and_deprecators(recwarn): @mpl._api.rename_parameter("(version)", "old", "new") @mpl._api.make_keyword_only("(version)", "kwo") def func(new, kwo=None): pass @plt._copy_docstring_and_deprecators(func) def wrapper_func(new, kwo=None): pass wrapper_func(None) wrapper_func(new=None) wrapper_func(None, kwo=None) wrapper_func(new=None, kwo=None) assert not recwarn with pytest.warns(MatplotlibDeprecationWarning): wrapper_func(old=None) with pytest.warns(MatplotlibDeprecationWarning): wrapper_func(None, None) def test_pyplot_box(): fig, ax = plt.subplots() plt.box(False) assert not ax.get_frame_on() plt.box(True) assert ax.get_frame_on() plt.box() assert not ax.get_frame_on() plt.box() assert ax.get_frame_on() def test_stackplot_smoke(): # Small smoke test for stackplot (see #12405) plt.stackplot([1, 2, 3], [1, 2, 3]) def test_nrows_error(): with pytest.raises(TypeError): plt.subplot(nrows=1) with pytest.raises(TypeError): plt.subplot(ncols=1) def test_ioff(): plt.ion() assert mpl.is_interactive() with plt.ioff(): assert not mpl.is_interactive() assert mpl.is_interactive() plt.ioff() assert not mpl.is_interactive() with plt.ioff(): assert not mpl.is_interactive() assert not mpl.is_interactive() def test_ion(): plt.ioff() assert not mpl.is_interactive() with plt.ion(): assert mpl.is_interactive() assert not mpl.is_interactive() plt.ion() assert mpl.is_interactive() with plt.ion(): assert mpl.is_interactive() assert mpl.is_interactive() def test_nested_ion_ioff(): # initial state is interactive plt.ion() # mixed ioff/ion with plt.ioff(): assert not mpl.is_interactive() with plt.ion(): assert mpl.is_interactive() assert not mpl.is_interactive() assert mpl.is_interactive() # redundant contexts with plt.ioff(): with plt.ioff(): assert not mpl.is_interactive() assert mpl.is_interactive() with plt.ion(): plt.ioff() assert mpl.is_interactive() # initial state is not interactive plt.ioff() # mixed ioff/ion with plt.ion(): assert mpl.is_interactive() with plt.ioff(): assert not mpl.is_interactive() assert mpl.is_interactive() assert not mpl.is_interactive() # redundant contexts with plt.ion(): with plt.ion(): assert mpl.is_interactive() assert not mpl.is_interactive() with plt.ioff(): plt.ion() assert not mpl.is_interactive() def test_close(): try: plt.close(1.1) except TypeError as e: assert str(e) == "close() argument must be a Figure, an int, " \ "a string, or None, not " def test_subplot_reuse(): ax1 = plt.subplot(121) assert ax1 is plt.gca() ax2 = plt.subplot(122) assert ax2 is plt.gca() ax3 = plt.subplot(121) assert ax1 is plt.gca() assert ax1 is ax3 def test_axes_kwargs(): # plt.axes() always creates new axes, even if axes kwargs differ. plt.figure() ax = plt.axes() ax1 = plt.axes() assert ax is not None assert ax1 is not ax plt.close() plt.figure() ax = plt.axes(projection='polar') ax1 = plt.axes(projection='polar') assert ax is not None assert ax1 is not ax plt.close() plt.figure() ax = plt.axes(projection='polar') ax1 = plt.axes() assert ax is not None assert ax1.name == 'rectilinear' assert ax1 is not ax plt.close() def test_subplot_replace_projection(): # plt.subplot() searches for axes with the same subplot spec, and if one # exists, and the kwargs match returns it, create a new one if they do not fig = plt.figure() ax = plt.subplot(1, 2, 1) ax1 = plt.subplot(1, 2, 1) ax2 = plt.subplot(1, 2, 2) # This will delete ax / ax1 as they fully overlap ax3 = plt.subplot(1, 2, 1, projection='polar') ax4 = plt.subplot(1, 2, 1, projection='polar') assert ax is not None assert ax1 is ax assert ax2 is not ax assert ax3 is not ax assert ax3 is ax4 assert ax not in fig.axes assert ax2 in fig.axes assert ax3 in fig.axes assert ax.name == 'rectilinear' assert ax2.name == 'rectilinear' assert ax3.name == 'polar' def test_subplot_kwarg_collision(): ax1 = plt.subplot(projection='polar', theta_offset=0) ax2 = plt.subplot(projection='polar', theta_offset=0) assert ax1 is ax2 ax3 = plt.subplot(projection='polar', theta_offset=1) assert ax1 is not ax3 assert ax1 not in plt.gcf().axes def test_gca_kwargs(): # plt.gca() returns an existing axes, unless there were no axes. plt.figure() ax = plt.gca() ax1 = plt.gca() assert ax is not None assert ax1 is ax plt.close() # plt.gca() raises a DeprecationWarning if called with kwargs. plt.figure() with pytest.warns( MatplotlibDeprecationWarning, match=r'Calling gca\(\) with keyword arguments was deprecated'): ax = plt.gca(projection='polar') ax1 = plt.gca() assert ax is not None assert ax1 is ax assert ax1.name == 'polar' plt.close() # plt.gca() ignores keyword arguments if an axes already exists. plt.figure() ax = plt.gca() with pytest.warns( MatplotlibDeprecationWarning, match=r'Calling gca\(\) with keyword arguments was deprecated'): ax1 = plt.gca(projection='polar') assert ax is not None assert ax1 is ax assert ax1.name == 'rectilinear' plt.close() def test_subplot_projection_reuse(): # create an axes ax1 = plt.subplot(111) # check that it is current assert ax1 is plt.gca() # make sure we get it back if we ask again assert ax1 is plt.subplot(111) # create a polar plot ax2 = plt.subplot(111, projection='polar') assert ax2 is plt.gca() # this should have deleted the first axes assert ax1 not in plt.gcf().axes # assert we get it back if no extra parameters passed assert ax2 is plt.subplot(111) # now check explicitly setting the projection to rectilinear # makes a new axes ax3 = plt.subplot(111, projection='rectilinear') assert ax3 is plt.gca() assert ax3 is not ax2 assert ax2 not in plt.gcf().axes def test_subplot_polar_normalization(): ax1 = plt.subplot(111, projection='polar') ax2 = plt.subplot(111, polar=True) ax3 = plt.subplot(111, polar=True, projection='polar') assert ax1 is ax2 assert ax1 is ax3 with pytest.raises(ValueError, match="polar=True, yet projection='3d'"): ax2 = plt.subplot(111, polar=True, projection='3d') def test_subplot_change_projection(): ax = plt.subplot() projections = ('aitoff', 'hammer', 'lambert', 'mollweide', 'polar', 'rectilinear', '3d') for proj in projections: ax_next = plt.subplot(projection=proj) assert ax_next is plt.subplot() assert ax_next.name == proj assert ax is not ax_next ax = ax_next def test_polar_second_call(): # the first call creates the axes with polar projection ln1, = plt.polar(0., 1., 'ro') assert isinstance(ln1, mpl.lines.Line2D) # the second call should reuse the existing axes ln2, = plt.polar(1.57, .5, 'bo') assert isinstance(ln2, mpl.lines.Line2D) assert ln1.axes is ln2.axes def test_fallback_position(): # check that position kwarg works if rect not supplied axref = plt.axes([0.2, 0.2, 0.5, 0.5]) axtest = plt.axes(position=[0.2, 0.2, 0.5, 0.5]) np.testing.assert_allclose(axtest.bbox.get_points(), axref.bbox.get_points()) # check that position kwarg ignored if rect is supplied axref = plt.axes([0.2, 0.2, 0.5, 0.5]) axtest = plt.axes([0.2, 0.2, 0.5, 0.5], position=[0.1, 0.1, 0.8, 0.8]) np.testing.assert_allclose(axtest.bbox.get_points(), axref.bbox.get_points())