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	import datetime
	import platform
	import re

	import contourpy
	import numpy as np
	from numpy.testing import (
	assert_array_almost_equal, assert_array_almost_equal_nulp)
	import matplotlib as mpl
	from matplotlib.testing.decorators import image_comparison
	from matplotlib import pyplot as plt, rc_context, ticker
	from matplotlib.colors import LogNorm, same_color
	import pytest


	def test_contour_shape_1d_valid():

	x = np.arange(10)
	y = np.arange(9)
	z = np.random.random((9, 10))

	fig, ax = plt.subplots()
	ax.contour(x, y, z)


	def test_contour_shape_2d_valid():

	x = np.arange(10)
	y = np.arange(9)
	xg, yg = np.meshgrid(x, y)
	z = np.random.random((9, 10))

	fig, ax = plt.subplots()
	ax.contour(xg, yg, z)


	@pytest.mark.parametrize("args, message", [
	((np.arange(9), np.arange(9), np.empty((9, 10))),
	'Length of x (9) must match number of columns in z (10)'),
	((np.arange(10), np.arange(10), np.empty((9, 10))),
	'Length of y (10) must match number of rows in z (9)'),
	((np.empty((10, 10)), np.arange(10), np.empty((9, 10))),
	'Number of dimensions of x (2) and y (1) do not match'),
	((np.arange(10), np.empty((10, 10)), np.empty((9, 10))),
	'Number of dimensions of x (1) and y (2) do not match'),
	((np.empty((9, 9)), np.empty((9, 10)), np.empty((9, 10))),
	'Shapes of x (9, 9) and z (9, 10) do not match'),
	((np.empty((9, 10)), np.empty((9, 9)), np.empty((9, 10))),
	'Shapes of y (9, 9) and z (9, 10) do not match'),
	((np.empty((3, 3, 3)), np.empty((3, 3, 3)), np.empty((9, 10))),
	'Inputs x and y must be 1D or 2D, not 3D'),
	((np.empty((3, 3, 3)), np.empty((3, 3, 3)), np.empty((3, 3, 3))),
	'Input z must be 2D, not 3D'),
	(([[0]],), # github issue 8197
	'Input z must be at least a (2, 2) shaped array, but has shape (1, 1)'),
	(([0], [0], [[0]]),
	'Input z must be at least a (2, 2) shaped array, but has shape (1, 1)'),
	])
	def test_contour_shape_error(args, message):
	fig, ax = plt.subplots()
	with pytest.raises(TypeError, match=re.escape(message)):
	ax.contour(*args)


	def test_contour_no_valid_levels():
	fig, ax = plt.subplots()
	# no warning for empty levels.
	ax.contour(np.random.rand(9, 9), levels=[])
	# no warning if levels is given and is not within the range of z.
	cs = ax.contour(np.arange(81).reshape((9, 9)), levels=[100])
	# ... and if fmt is given.
	ax.clabel(cs, fmt={100: '%1.2f'})
	# no warning if z is uniform.
	ax.contour(np.ones((9, 9)))


	def test_contour_Nlevels():
	# A scalar levels arg or kwarg should trigger auto level generation.
	# https://github.com/matplotlib/matplotlib/issues/11913
	z = np.arange(12).reshape((3, 4))
	fig, ax = plt.subplots()
	cs1 = ax.contour(z, 5)
	assert len(cs1.levels) > 1
	cs2 = ax.contour(z, levels=5)
	assert (cs1.levels == cs2.levels).all()


	@image_comparison(['contour_manual_labels'], remove_text=True, style='mpl20')
	def test_contour_manual_labels():
	x, y = np.meshgrid(np.arange(0, 10), np.arange(0, 10))
	z = np.max(np.dstack([abs(x), abs(y)]), 2)

	plt.figure(figsize=(6, 2), dpi=200)
	cs = plt.contour(x, y, z)
	pts = np.array([(1.0, 3.0), (1.0, 4.4), (1.0, 6.0)])
	plt.clabel(cs, manual=pts)
	pts = np.array([(2.0, 3.0), (2.0, 4.4), (2.0, 6.0)])
	plt.clabel(cs, manual=pts, fontsize='small', colors=('r', 'g'))


	@image_comparison(['contour_manual_colors_and_levels.png'], remove_text=True)
	def test_given_colors_levels_and_extends():
	# Remove this line when this test image is regenerated.
	plt.rcParams['pcolormesh.snap'] = False

	_, axs = plt.subplots(2, 4)

	data = np.arange(12).reshape(3, 4)

	colors = ['red', 'yellow', 'pink', 'blue', 'black']
	levels = [2, 4, 8, 10]

	for i, ax in enumerate(axs.flat):
	filled = i % 2 == 0.
	extend = ['neither', 'min', 'max', 'both'][i // 2]

	if filled:
	# If filled, we have 3 colors with no extension,
	# 4 colors with one extension, and 5 colors with both extensions
	first_color = 1 if extend in ['max', 'neither'] else None
	last_color = -1 if extend in ['min', 'neither'] else None
	c = ax.contourf(data, colors=colors[first_color:last_color],
	levels=levels, extend=extend)
	else:
	# If not filled, we have 4 levels and 4 colors
	c = ax.contour(data, colors=colors[:-1],
	levels=levels, extend=extend)

	plt.colorbar(c, ax=ax)


	@image_comparison(['contour_log_locator.svg'], style='mpl20',
	remove_text=False)
	def test_log_locator_levels():

	fig, ax = plt.subplots()

	N = 100
	x = np.linspace(-3.0, 3.0, N)
	y = np.linspace(-2.0, 2.0, N)

	X, Y = np.meshgrid(x, y)

	Z1 = np.exp(-X2 - Y2)
	Z2 = np.exp(-(X * 10)*2 - (Y 10)**2)
	data = Z1 + 50 * Z2

	c = ax.contourf(data, locator=ticker.LogLocator())
	assert_array_almost_equal(c.levels, np.power(10.0, np.arange(-6, 3)))
	cb = fig.colorbar(c, ax=ax)
	assert_array_almost_equal(cb.ax.get_yticks(), c.levels)


	@image_comparison(['contour_datetime_axis.png'], style='mpl20')
	def test_contour_datetime_axis():
	fig = plt.figure()
	fig.subplots_adjust(hspace=0.4, top=0.98, bottom=.15)
	base = datetime.datetime(2013, 1, 1)
	x = np.array([base + datetime.timedelta(days=d) for d in range(20)])
	y = np.arange(20)
	z1, z2 = np.meshgrid(np.arange(20), np.arange(20))
	z = z1 * z2
	plt.subplot(221)
	plt.contour(x, y, z)
	plt.subplot(222)
	plt.contourf(x, y, z)
	x = np.repeat(x[np.newaxis], 20, axis=0)
	y = np.repeat(y[:, np.newaxis], 20, axis=1)
	plt.subplot(223)
	plt.contour(x, y, z)
	plt.subplot(224)
	plt.contourf(x, y, z)
	for ax in fig.get_axes():
	for label in ax.get_xticklabels():
	label.set_ha('right')
	label.set_rotation(30)


	@image_comparison(['contour_test_label_transforms.png'],
	remove_text=True, style='mpl20',
	tol=0 if platform.machine() == 'x86_64' else 0.08)
	def test_labels():
	# Adapted from pylab_examples example code: contour_demo.py
	# see issues #2475, #2843, and #2818 for explanation
	delta = 0.025
	x = np.arange(-3.0, 3.0, delta)
	y = np.arange(-2.0, 2.0, delta)
	X, Y = np.meshgrid(x, y)
	Z1 = np.exp(-(X2 + Y2) / 2) / (2 * np.pi)
	Z2 = (np.exp(-(((X - 1) / 1.5)2 + ((Y - 1) / 0.5)2) / 2) /
	(2 * np.pi * 0.5 * 1.5))

	# difference of Gaussians
	Z = 10.0 * (Z2 - Z1)

	fig, ax = plt.subplots(1, 1)
	CS = ax.contour(X, Y, Z)
	disp_units = [(216, 177), (359, 290), (521, 406)]
	data_units = [(-2, .5), (0, -1.5), (2.8, 1)]

	CS.clabel()

	for x, y in data_units:
	CS.add_label_near(x, y, inline=True, transform=None)

	for x, y in disp_units:
	CS.add_label_near(x, y, inline=True, transform=False)


	@image_comparison(['contour_corner_mask_False.png',
	'contour_corner_mask_True.png'],
	remove_text=True)
	def test_corner_mask():
	n = 60
	mask_level = 0.95
	noise_amp = 1.0
	np.random.seed([1])
	x, y = np.meshgrid(np.linspace(0, 2.0, n), np.linspace(0, 2.0, n))
	z = np.cos(7x)np.sin(8y) + noise_ampnp.random.rand(n, n)
	mask = np.random.rand(n, n) >= mask_level
	z = np.ma.array(z, mask=mask)

	for corner_mask in [False, True]:
	plt.figure()
	plt.contourf(z, corner_mask=corner_mask)


	def test_contourf_decreasing_levels():
	# github issue 5477.
	z = [[0.1, 0.3], [0.5, 0.7]]
	plt.figure()
	with pytest.raises(ValueError):
	plt.contourf(z, [1.0, 0.0])


	def test_contourf_symmetric_locator():
	# github issue 7271
	z = np.arange(12).reshape((3, 4))
	locator = plt.MaxNLocator(nbins=4, symmetric=True)
	cs = plt.contourf(z, locator=locator)
	assert_array_almost_equal(cs.levels, np.linspace(-12, 12, 5))


	def test_circular_contour_warning():
	# Check that almost circular contours don't throw a warning
	x, y = np.meshgrid(np.linspace(-2, 2, 4), np.linspace(-2, 2, 4))
	r = np.hypot(x, y)
	plt.figure()
	cs = plt.contour(x, y, r)
	plt.clabel(cs)


	@pytest.mark.parametrize("use_clabeltext, contour_zorder, clabel_zorder",
	[(True, 123, 1234), (False, 123, 1234),
	(True, 123, None), (False, 123, None)])
	def test_clabel_zorder(use_clabeltext, contour_zorder, clabel_zorder):
	x, y = np.meshgrid(np.arange(0, 10), np.arange(0, 10))
	z = np.max(np.dstack([abs(x), abs(y)]), 2)

	fig, (ax1, ax2) = plt.subplots(ncols=2)
	cs = ax1.contour(x, y, z, zorder=contour_zorder)
	cs_filled = ax2.contourf(x, y, z, zorder=contour_zorder)
	clabels1 = cs.clabel(zorder=clabel_zorder, use_clabeltext=use_clabeltext)
	clabels2 = cs_filled.clabel(zorder=clabel_zorder,
	use_clabeltext=use_clabeltext)

	if clabel_zorder is None:
	expected_clabel_zorder = 2+contour_zorder
	else:
	expected_clabel_zorder = clabel_zorder

	for clabel in clabels1:
	assert clabel.get_zorder() == expected_clabel_zorder
	for clabel in clabels2:
	assert clabel.get_zorder() == expected_clabel_zorder


	# tol because ticks happen to fall on pixel boundaries so small
	# floating point changes in tick location flip which pixel gets
	# the tick.
	@image_comparison(['contour_log_extension.png'],
	remove_text=True, style='mpl20',
	tol=1.444)
	def test_contourf_log_extension():
	# Remove this line when this test image is regenerated.
	plt.rcParams['pcolormesh.snap'] = False

	# Test that contourf with lognorm is extended correctly
	fig, (ax1, ax2, ax3) = plt.subplots(1, 3, figsize=(10, 5))
	fig.subplots_adjust(left=0.05, right=0.95)

	# make data set with large range e.g. between 1e-8 and 1e10
	data_exp = np.linspace(-7.5, 9.5, 1200)
	data = np.power(10, data_exp).reshape(30, 40)
	# make manual levels e.g. between 1e-4 and 1e-6
	levels_exp = np.arange(-4., 7.)
	levels = np.power(10., levels_exp)

	# original data
	c1 = ax1.contourf(data,
	norm=LogNorm(vmin=data.min(), vmax=data.max()))
	# just show data in levels
	c2 = ax2.contourf(data, levels=levels,
	norm=LogNorm(vmin=levels.min(), vmax=levels.max()),
	extend='neither')
	# extend data from levels
	c3 = ax3.contourf(data, levels=levels,
	norm=LogNorm(vmin=levels.min(), vmax=levels.max()),
	extend='both')
	cb = plt.colorbar(c1, ax=ax1)
	assert cb.ax.get_ylim() == (1e-8, 1e10)
	cb = plt.colorbar(c2, ax=ax2)
	assert_array_almost_equal_nulp(cb.ax.get_ylim(), np.array((1e-4, 1e6)))
	cb = plt.colorbar(c3, ax=ax3)


	@image_comparison(
	['contour_addlines.png'], remove_text=True, style='mpl20',
	tol=0.15 if platform.machine() in ('aarch64', 'ppc64le', 's390x')
	else 0.03)
	# tolerance is because image changed minutely when tick finding on
	# colorbars was cleaned up...
	def test_contour_addlines():
	# Remove this line when this test image is regenerated.
	plt.rcParams['pcolormesh.snap'] = False

	fig, ax = plt.subplots()
	np.random.seed(19680812)
	X = np.random.rand(10, 10)*10000
	pcm = ax.pcolormesh(X)
	# add 1000 to make colors visible...
	cont = ax.contour(X+1000)
	cb = fig.colorbar(pcm)
	cb.add_lines(cont)
	assert_array_almost_equal(cb.ax.get_ylim(), [114.3091, 9972.30735], 3)


	@image_comparison(baseline_images=['contour_uneven'],
	extensions=['png'], remove_text=True, style='mpl20')
	def test_contour_uneven():
	# Remove this line when this test image is regenerated.
	plt.rcParams['pcolormesh.snap'] = False

	z = np.arange(24).reshape(4, 6)
	fig, axs = plt.subplots(1, 2)
	ax = axs[0]
	cs = ax.contourf(z, levels=[2, 4, 6, 10, 20])
	fig.colorbar(cs, ax=ax, spacing='proportional')
	ax = axs[1]
	cs = ax.contourf(z, levels=[2, 4, 6, 10, 20])
	fig.colorbar(cs, ax=ax, spacing='uniform')


	@pytest.mark.parametrize(
	"rc_lines_linewidth, rc_contour_linewidth, call_linewidths, expected", [
	(1.23, None, None, 1.23),
	(1.23, 4.24, None, 4.24),
	(1.23, 4.24, 5.02, 5.02)
	])
	def test_contour_linewidth(
	rc_lines_linewidth, rc_contour_linewidth, call_linewidths, expected):

	with rc_context(rc={"lines.linewidth": rc_lines_linewidth,
	"contour.linewidth": rc_contour_linewidth}):
	fig, ax = plt.subplots()
	X = np.arange(4*3).reshape(4, 3)
	cs = ax.contour(X, linewidths=call_linewidths)
	assert cs.tlinewidths[0][0] == expected


	@pytest.mark.backend("pdf")
	def test_label_nonagg():
	# This should not crash even if the canvas doesn't have a get_renderer().
	plt.clabel(plt.contour([[1, 2], [3, 4]]))


	@image_comparison(baseline_images=['contour_closed_line_loop'],
	extensions=['png'], remove_text=True)
	def test_contour_closed_line_loop():
	# github issue 19568.
	z = [[0, 0, 0], [0, 2, 0], [0, 0, 0], [2, 1, 2]]

	fig, ax = plt.subplots(figsize=(2, 2))
	ax.contour(z, [0.5], linewidths=[20], alpha=0.7)
	ax.set_xlim(-0.1, 2.1)
	ax.set_ylim(-0.1, 3.1)


	def test_quadcontourset_reuse():
	# If QuadContourSet returned from one contour(f) call is passed as first
	# argument to another the underlying C++ contour generator will be reused.
	x, y = np.meshgrid([0.0, 1.0], [0.0, 1.0])
	z = x + y
	fig, ax = plt.subplots()
	qcs1 = ax.contourf(x, y, z)
	qcs2 = ax.contour(x, y, z)
	assert qcs2._contour_generator != qcs1._contour_generator
	qcs3 = ax.contour(qcs1, z)
	assert qcs3._contour_generator == qcs1._contour_generator


	@image_comparison(baseline_images=['contour_manual'],
	extensions=['png'], remove_text=True)
	def test_contour_manual():
	# Manually specifying contour lines/polygons to plot.
	from matplotlib.contour import ContourSet

	fig, ax = plt.subplots(figsize=(4, 4))
	cmap = 'viridis'

	# Segments only (no 'kind' codes).
	lines0 = [[[2, 0], [1, 2], [1, 3]]] # Single line.
	lines1 = [[[3, 0], [3, 2]], [[3, 3], [3, 4]]] # Two lines.
	filled01 = [[[0, 0], [0, 4], [1, 3], [1, 2], [2, 0]]]
	filled12 = [[[2, 0], [3, 0], [3, 2], [1, 3], [1, 2]], # Two polygons.
	[[1, 4], [3, 4], [3, 3]]]
	ContourSet(ax, [0, 1, 2], [filled01, filled12], filled=True, cmap=cmap)
	ContourSet(ax, [1, 2], [lines0, lines1], linewidths=3, colors=['r', 'k'])

	# Segments and kind codes (1 = MOVETO, 2 = LINETO, 79 = CLOSEPOLY).
	segs = [[[4, 0], [7, 0], [7, 3], [4, 3], [4, 0],
	[5, 1], [5, 2], [6, 2], [6, 1], [5, 1]]]
	kinds = [[1, 2, 2, 2, 79, 1, 2, 2, 2, 79]] # Polygon containing hole.
	ContourSet(ax, [2, 3], [segs], [kinds], filled=True, cmap=cmap)
	ContourSet(ax, [2], [segs], [kinds], colors='k', linewidths=3)


	@image_comparison(baseline_images=['contour_line_start_on_corner_edge'],
	extensions=['png'], remove_text=True)
	def test_contour_line_start_on_corner_edge():
	fig, ax = plt.subplots(figsize=(6, 5))

	x, y = np.meshgrid([0, 1, 2, 3, 4], [0, 1, 2])
	z = 1.2 - (x - 2)2 + (y - 1)2
	mask = np.zeros_like(z, dtype=bool)
	mask[1, 1] = mask[1, 3] = True
	z = np.ma.array(z, mask=mask)

	filled = ax.contourf(x, y, z, corner_mask=True)
	cbar = fig.colorbar(filled)
	lines = ax.contour(x, y, z, corner_mask=True, colors='k')
	cbar.add_lines(lines)


	def test_find_nearest_contour():
	xy = np.indices((15, 15))
	img = np.exp(-np.pi * (np.sum((xy - 5)2, 0)/5.2))
	cs = plt.contour(img, 10)

	nearest_contour = cs.find_nearest_contour(1, 1, pixel=False)
	expected_nearest = (1, 0, 33, 1.965966, 1.965966, 1.866183)
	assert_array_almost_equal(nearest_contour, expected_nearest)

	nearest_contour = cs.find_nearest_contour(8, 1, pixel=False)
	expected_nearest = (1, 0, 5, 7.550173, 1.587542, 0.547550)
	assert_array_almost_equal(nearest_contour, expected_nearest)

	nearest_contour = cs.find_nearest_contour(2, 5, pixel=False)
	expected_nearest = (3, 0, 21, 1.884384, 5.023335, 0.013911)
	assert_array_almost_equal(nearest_contour, expected_nearest)

	nearest_contour = cs.find_nearest_contour(2, 5,
	indices=(5, 7),
	pixel=False)
	expected_nearest = (5, 0, 16, 2.628202, 5.0, 0.394638)
	assert_array_almost_equal(nearest_contour, expected_nearest)


	def test_find_nearest_contour_no_filled():
	xy = np.indices((15, 15))
	img = np.exp(-np.pi * (np.sum((xy - 5)2, 0)/5.2))
	cs = plt.contourf(img, 10)

	with pytest.raises(ValueError,
	match="Method does not support filled contours."):
	cs.find_nearest_contour(1, 1, pixel=False)

	with pytest.raises(ValueError,
	match="Method does not support filled contours."):
	cs.find_nearest_contour(1, 10, indices=(5, 7), pixel=False)

	with pytest.raises(ValueError,
	match="Method does not support filled contours."):
	cs.find_nearest_contour(2, 5, indices=(2, 7), pixel=True)


	@mpl.style.context("default")
	def test_contour_autolabel_beyond_powerlimits():
	ax = plt.figure().add_subplot()
	cs = plt.contour(np.geomspace(1e-6, 1e-4, 100).reshape(10, 10),
	levels=[.25e-5, 1e-5, 4e-5])
	ax.clabel(cs)
	# Currently, the exponent is missing, but that may be fixed in the future.
	assert {text.get_text() for text in ax.texts} == {"0.25", "1.00", "4.00"}


	def test_contourf_legend_elements():
	from matplotlib.patches import Rectangle
	x = np.arange(1, 10)
	y = x.reshape(-1, 1)
	h = x * y

	cs = plt.contourf(h, levels=[10, 30, 50],
	colors=['#FFFF00', '#FF00FF', '#00FFFF'],
	extend='both')
	cs.cmap.set_over('red')
	cs.cmap.set_under('blue')
	cs.changed()
	artists, labels = cs.legend_elements()
	assert labels == ['$x \\leq -1e+250s$',
	'$10.0 < x \\leq 30.0$',
	'$30.0 < x \\leq 50.0$',
	'$x > 1e+250s$']
	expected_colors = ('blue', '#FFFF00', '#FF00FF', 'red')
	assert all(isinstance(a, Rectangle) for a in artists)
	assert all(same_color(a.get_facecolor(), c)
	for a, c in zip(artists, expected_colors))


	def test_contour_legend_elements():
	from matplotlib.collections import LineCollection
	x = np.arange(1, 10)
	y = x.reshape(-1, 1)
	h = x * y

	colors = ['blue', '#00FF00', 'red']
	cs = plt.contour(h, levels=[10, 30, 50],
	colors=colors,
	extend='both')
	artists, labels = cs.legend_elements()
	assert labels == ['$x = 10.0$', '$x = 30.0$', '$x = 50.0$']
	assert all(isinstance(a, LineCollection) for a in artists)
	assert all(same_color(a.get_color(), c)
	for a, c in zip(artists, colors))


	@pytest.mark.parametrize(
	"algorithm, klass",
	[('mpl2005', contourpy.Mpl2005ContourGenerator),
	('mpl2014', contourpy.Mpl2014ContourGenerator),
	('serial', contourpy.SerialContourGenerator),
	('threaded', contourpy.ThreadedContourGenerator),
	('invalid', None)])
	def test_algorithm_name(algorithm, klass):
	z = np.array([[1.0, 2.0], [3.0, 4.0]])
	if klass is not None:
	cs = plt.contourf(z, algorithm=algorithm)
	assert isinstance(cs._contour_generator, klass)
	else:
	with pytest.raises(ValueError):
	plt.contourf(z, algorithm=algorithm)


	@pytest.mark.parametrize(
	"algorithm", ['mpl2005', 'mpl2014', 'serial', 'threaded'])
	def test_algorithm_supports_corner_mask(algorithm):
	z = np.array([[1.0, 2.0], [3.0, 4.0]])

	# All algorithms support corner_mask=False
	plt.contourf(z, algorithm=algorithm, corner_mask=False)

	# Only some algorithms support corner_mask=True
	if algorithm != 'mpl2005':
	plt.contourf(z, algorithm=algorithm, corner_mask=True)
	else:
	with pytest.raises(ValueError):
	plt.contourf(z, algorithm=algorithm, corner_mask=True)


	@image_comparison(baseline_images=['contour_all_algorithms'],
	extensions=['png'], remove_text=True)
	def test_all_algorithms():
	algorithms = ['mpl2005', 'mpl2014', 'serial', 'threaded']

	rng = np.random.default_rng(2981)
	x, y = np.meshgrid(np.linspace(0.0, 1.0, 10), np.linspace(0.0, 1.0, 6))
	z = np.sin(15x)np.cos(10*y) + rng.normal(scale=0.5, size=(6, 10))
	mask = np.zeros_like(z, dtype=bool)
	mask[3, 7] = True
	z = np.ma.array(z, mask=mask)

	_, axs = plt.subplots(2, 2)
	for ax, algorithm in zip(axs.ravel(), algorithms):
	ax.contourf(x, y, z, algorithm=algorithm)
	ax.contour(x, y, z, algorithm=algorithm, colors='k')
	ax.set_title(algorithm)


	def test_subfigure_clabel():
	# Smoke test for gh#23173
	delta = 0.025
	x = np.arange(-3.0, 3.0, delta)
	y = np.arange(-2.0, 2.0, delta)
	X, Y = np.meshgrid(x, y)
	Z1 = np.exp(-(X2) - Y2)
	Z2 = np.exp(-((X - 1) 2) - (Y - 1) 2)
	Z = (Z1 - Z2) * 2

	fig = plt.figure()
	figs = fig.subfigures(nrows=1, ncols=2)

	for f in figs:
	ax = f.subplots()
	CS = ax.contour(X, Y, Z)
	ax.clabel(CS, inline=True, fontsize=10)
	ax.set_title("Simplest default with labels")


	@pytest.mark.parametrize(
	"style", ['solid', 'dashed', 'dashdot', 'dotted'])
	def test_linestyles(style):
	delta = 0.025
	x = np.arange(-3.0, 3.0, delta)
	y = np.arange(-2.0, 2.0, delta)
	X, Y = np.meshgrid(x, y)
	Z1 = np.exp(-X2 - Y2)
	Z2 = np.exp(-(X - 1)2 - (Y - 1)2)
	Z = (Z1 - Z2) * 2

	# Positive contour defaults to solid
	fig1, ax1 = plt.subplots()
	CS1 = ax1.contour(X, Y, Z, 6, colors='k')
	ax1.clabel(CS1, fontsize=9, inline=True)
	ax1.set_title('Single color - positive contours solid (default)')
	assert CS1.linestyles is None # default

	# Change linestyles using linestyles kwarg
	fig2, ax2 = plt.subplots()
	CS2 = ax2.contour(X, Y, Z, 6, colors='k', linestyles=style)
	ax2.clabel(CS2, fontsize=9, inline=True)
	ax2.set_title(f'Single color - positive contours {style}')
	assert CS2.linestyles == style

	# Ensure linestyles do not change when negative_linestyles is defined
	fig3, ax3 = plt.subplots()
	CS3 = ax3.contour(X, Y, Z, 6, colors='k', linestyles=style,
	negative_linestyles='dashdot')
	ax3.clabel(CS3, fontsize=9, inline=True)
	ax3.set_title(f'Single color - positive contours {style}')
	assert CS3.linestyles == style


	@pytest.mark.parametrize(
	"style", ['solid', 'dashed', 'dashdot', 'dotted'])
	def test_negative_linestyles(style):
	delta = 0.025
	x = np.arange(-3.0, 3.0, delta)
	y = np.arange(-2.0, 2.0, delta)
	X, Y = np.meshgrid(x, y)
	Z1 = np.exp(-X2 - Y2)
	Z2 = np.exp(-(X - 1)2 - (Y - 1)2)
	Z = (Z1 - Z2) * 2

	# Negative contour defaults to dashed
	fig1, ax1 = plt.subplots()
	CS1 = ax1.contour(X, Y, Z, 6, colors='k')
	ax1.clabel(CS1, fontsize=9, inline=True)
	ax1.set_title('Single color - negative contours dashed (default)')
	assert CS1.negative_linestyles == 'dashed' # default

	# Change negative_linestyles using rcParams
	plt.rcParams['contour.negative_linestyle'] = style
	fig2, ax2 = plt.subplots()
	CS2 = ax2.contour(X, Y, Z, 6, colors='k')
	ax2.clabel(CS2, fontsize=9, inline=True)
	ax2.set_title(f'Single color - negative contours {style}'
	'(using rcParams)')
	assert CS2.negative_linestyles == style

	# Change negative_linestyles using negative_linestyles kwarg
	fig3, ax3 = plt.subplots()
	CS3 = ax3.contour(X, Y, Z, 6, colors='k', negative_linestyles=style)
	ax3.clabel(CS3, fontsize=9, inline=True)
	ax3.set_title(f'Single color - negative contours {style}')
	assert CS3.negative_linestyles == style

	# Ensure negative_linestyles do not change when linestyles is defined
	fig4, ax4 = plt.subplots()
	CS4 = ax4.contour(X, Y, Z, 6, colors='k', linestyles='dashdot',
	negative_linestyles=style)
	ax4.clabel(CS4, fontsize=9, inline=True)
	ax4.set_title(f'Single color - negative contours {style}')
	assert CS4.negative_linestyles == style


	def test_contour_remove():
	ax = plt.figure().add_subplot()
	orig_children = ax.get_children()
	cs = ax.contour(np.arange(16).reshape((4, 4)))
	cs.clabel()
	assert ax.get_children() != orig_children
	cs.remove()
	assert ax.get_children() == orig_children


	def test_bool_autolevel():
	x, y = np.random.rand(2, 9)
	z = (np.arange(9) % 2).reshape((3, 3)).astype(bool)
	m = [[False, False, False], [False, True, False], [False, False, False]]
	assert plt.contour(z.tolist()).levels.tolist() == [.5]
	assert plt.contour(z).levels.tolist() == [.5]
	assert plt.contour(np.ma.array(z, mask=m)).levels.tolist() == [.5]
	assert plt.contourf(z.tolist()).levels.tolist() == [0, .5, 1]
	assert plt.contourf(z).levels.tolist() == [0, .5, 1]
	assert plt.contourf(np.ma.array(z, mask=m)).levels.tolist() == [0, .5, 1]
	z = z.ravel()
	assert plt.tricontour(x, y, z.tolist()).levels.tolist() == [.5]
	assert plt.tricontour(x, y, z).levels.tolist() == [.5]
	assert plt.tricontourf(x, y, z.tolist()).levels.tolist() == [0, .5, 1]
	assert plt.tricontourf(x, y, z).levels.tolist() == [0, .5, 1]