craftbeerpi4-pione/venv3/lib/python3.7/site-packages/pandas/tests/plotting/test_series.py
2021-03-03 23:49:41 +01:00

981 lines
35 KiB
Python

""" Test cases for Series.plot """
from datetime import datetime
from itertools import chain
import numpy as np
from numpy.random import randn
import pytest
import pandas.util._test_decorators as td
import pandas as pd
from pandas import DataFrame, Series, date_range
import pandas._testing as tm
from pandas.tests.plotting.common import TestPlotBase, _check_plot_works
import pandas.plotting as plotting
@td.skip_if_no_mpl
class TestSeriesPlots(TestPlotBase):
def setup_method(self, method):
TestPlotBase.setup_method(self, method)
import matplotlib as mpl
mpl.rcdefaults()
self.ts = tm.makeTimeSeries()
self.ts.name = "ts"
self.series = tm.makeStringSeries()
self.series.name = "series"
self.iseries = tm.makePeriodSeries()
self.iseries.name = "iseries"
@pytest.mark.slow
def test_plot(self):
_check_plot_works(self.ts.plot, label="foo")
_check_plot_works(self.ts.plot, use_index=False)
axes = _check_plot_works(self.ts.plot, rot=0)
self._check_ticks_props(axes, xrot=0)
ax = _check_plot_works(self.ts.plot, style=".", logy=True)
self._check_ax_scales(ax, yaxis="log")
ax = _check_plot_works(self.ts.plot, style=".", logx=True)
self._check_ax_scales(ax, xaxis="log")
ax = _check_plot_works(self.ts.plot, style=".", loglog=True)
self._check_ax_scales(ax, xaxis="log", yaxis="log")
_check_plot_works(self.ts[:10].plot.bar)
_check_plot_works(self.ts.plot.area, stacked=False)
_check_plot_works(self.iseries.plot)
for kind in ["line", "bar", "barh", "kde", "hist", "box"]:
_check_plot_works(self.series[:5].plot, kind=kind)
_check_plot_works(self.series[:10].plot.barh)
ax = _check_plot_works(Series(randn(10)).plot.bar, color="black")
self._check_colors([ax.patches[0]], facecolors=["black"])
# GH 6951
ax = _check_plot_works(self.ts.plot, subplots=True)
self._check_axes_shape(ax, axes_num=1, layout=(1, 1))
ax = _check_plot_works(self.ts.plot, subplots=True, layout=(-1, 1))
self._check_axes_shape(ax, axes_num=1, layout=(1, 1))
ax = _check_plot_works(self.ts.plot, subplots=True, layout=(1, -1))
self._check_axes_shape(ax, axes_num=1, layout=(1, 1))
@pytest.mark.slow
def test_plot_figsize_and_title(self):
# figsize and title
_, ax = self.plt.subplots()
ax = self.series.plot(title="Test", figsize=(16, 8), ax=ax)
self._check_text_labels(ax.title, "Test")
self._check_axes_shape(ax, axes_num=1, layout=(1, 1), figsize=(16, 8))
def test_dont_modify_rcParams(self):
# GH 8242
key = "axes.prop_cycle"
colors = self.plt.rcParams[key]
_, ax = self.plt.subplots()
Series([1, 2, 3]).plot(ax=ax)
assert colors == self.plt.rcParams[key]
def test_ts_line_lim(self):
fig, ax = self.plt.subplots()
ax = self.ts.plot(ax=ax)
xmin, xmax = ax.get_xlim()
lines = ax.get_lines()
assert xmin <= lines[0].get_data(orig=False)[0][0]
assert xmax >= lines[0].get_data(orig=False)[0][-1]
tm.close()
ax = self.ts.plot(secondary_y=True, ax=ax)
xmin, xmax = ax.get_xlim()
lines = ax.get_lines()
assert xmin <= lines[0].get_data(orig=False)[0][0]
assert xmax >= lines[0].get_data(orig=False)[0][-1]
def test_ts_area_lim(self):
_, ax = self.plt.subplots()
ax = self.ts.plot.area(stacked=False, ax=ax)
xmin, xmax = ax.get_xlim()
line = ax.get_lines()[0].get_data(orig=False)[0]
assert xmin <= line[0]
assert xmax >= line[-1]
tm.close()
# GH 7471
_, ax = self.plt.subplots()
ax = self.ts.plot.area(stacked=False, x_compat=True, ax=ax)
xmin, xmax = ax.get_xlim()
line = ax.get_lines()[0].get_data(orig=False)[0]
assert xmin <= line[0]
assert xmax >= line[-1]
tm.close()
tz_ts = self.ts.copy()
tz_ts.index = tz_ts.tz_localize("GMT").tz_convert("CET")
_, ax = self.plt.subplots()
ax = tz_ts.plot.area(stacked=False, x_compat=True, ax=ax)
xmin, xmax = ax.get_xlim()
line = ax.get_lines()[0].get_data(orig=False)[0]
assert xmin <= line[0]
assert xmax >= line[-1]
tm.close()
_, ax = self.plt.subplots()
ax = tz_ts.plot.area(stacked=False, secondary_y=True, ax=ax)
xmin, xmax = ax.get_xlim()
line = ax.get_lines()[0].get_data(orig=False)[0]
assert xmin <= line[0]
assert xmax >= line[-1]
def test_label(self):
s = Series([1, 2])
_, ax = self.plt.subplots()
ax = s.plot(label="LABEL", legend=True, ax=ax)
self._check_legend_labels(ax, labels=["LABEL"])
self.plt.close()
_, ax = self.plt.subplots()
ax = s.plot(legend=True, ax=ax)
self._check_legend_labels(ax, labels=["None"])
self.plt.close()
# get name from index
s.name = "NAME"
_, ax = self.plt.subplots()
ax = s.plot(legend=True, ax=ax)
self._check_legend_labels(ax, labels=["NAME"])
self.plt.close()
# override the default
_, ax = self.plt.subplots()
ax = s.plot(legend=True, label="LABEL", ax=ax)
self._check_legend_labels(ax, labels=["LABEL"])
self.plt.close()
# Add lebel info, but don't draw
_, ax = self.plt.subplots()
ax = s.plot(legend=False, label="LABEL", ax=ax)
assert ax.get_legend() is None # Hasn't been drawn
ax.legend() # draw it
self._check_legend_labels(ax, labels=["LABEL"])
def test_boolean(self):
# GH 23719
s = Series([False, False, True])
_check_plot_works(s.plot, include_bool=True)
msg = "no numeric data to plot"
with pytest.raises(TypeError, match=msg):
_check_plot_works(s.plot)
def test_line_area_nan_series(self):
values = [1, 2, np.nan, 3]
s = Series(values)
ts = Series(values, index=tm.makeDateIndex(k=4))
for d in [s, ts]:
ax = _check_plot_works(d.plot)
masked = ax.lines[0].get_ydata()
# remove nan for comparison purpose
exp = np.array([1, 2, 3], dtype=np.float64)
tm.assert_numpy_array_equal(np.delete(masked.data, 2), exp)
tm.assert_numpy_array_equal(
masked.mask, np.array([False, False, True, False])
)
expected = np.array([1, 2, 0, 3], dtype=np.float64)
ax = _check_plot_works(d.plot, stacked=True)
tm.assert_numpy_array_equal(ax.lines[0].get_ydata(), expected)
ax = _check_plot_works(d.plot.area)
tm.assert_numpy_array_equal(ax.lines[0].get_ydata(), expected)
ax = _check_plot_works(d.plot.area, stacked=False)
tm.assert_numpy_array_equal(ax.lines[0].get_ydata(), expected)
def test_line_use_index_false(self):
s = Series([1, 2, 3], index=["a", "b", "c"])
s.index.name = "The Index"
_, ax = self.plt.subplots()
ax = s.plot(use_index=False, ax=ax)
label = ax.get_xlabel()
assert label == ""
_, ax = self.plt.subplots()
ax2 = s.plot.bar(use_index=False, ax=ax)
label2 = ax2.get_xlabel()
assert label2 == ""
@pytest.mark.slow
def test_bar_log(self):
expected = np.array([1e-1, 1e0, 1e1, 1e2, 1e3, 1e4])
_, ax = self.plt.subplots()
ax = Series([200, 500]).plot.bar(log=True, ax=ax)
tm.assert_numpy_array_equal(ax.yaxis.get_ticklocs(), expected)
tm.close()
_, ax = self.plt.subplots()
ax = Series([200, 500]).plot.barh(log=True, ax=ax)
tm.assert_numpy_array_equal(ax.xaxis.get_ticklocs(), expected)
tm.close()
# GH 9905
expected = np.array([1e-5, 1e-4, 1e-3, 1e-2, 1e-1, 1e0, 1e1])
_, ax = self.plt.subplots()
ax = Series([0.1, 0.01, 0.001]).plot(log=True, kind="bar", ax=ax)
ymin = 0.0007943282347242822
ymax = 0.12589254117941673
res = ax.get_ylim()
tm.assert_almost_equal(res[0], ymin)
tm.assert_almost_equal(res[1], ymax)
tm.assert_numpy_array_equal(ax.yaxis.get_ticklocs(), expected)
tm.close()
_, ax = self.plt.subplots()
ax = Series([0.1, 0.01, 0.001]).plot(log=True, kind="barh", ax=ax)
res = ax.get_xlim()
tm.assert_almost_equal(res[0], ymin)
tm.assert_almost_equal(res[1], ymax)
tm.assert_numpy_array_equal(ax.xaxis.get_ticklocs(), expected)
@pytest.mark.slow
def test_bar_ignore_index(self):
df = Series([1, 2, 3, 4], index=["a", "b", "c", "d"])
_, ax = self.plt.subplots()
ax = df.plot.bar(use_index=False, ax=ax)
self._check_text_labels(ax.get_xticklabels(), ["0", "1", "2", "3"])
def test_bar_user_colors(self):
s = Series([1, 2, 3, 4])
ax = s.plot.bar(color=["red", "blue", "blue", "red"])
result = [p.get_facecolor() for p in ax.patches]
expected = [
(1.0, 0.0, 0.0, 1.0),
(0.0, 0.0, 1.0, 1.0),
(0.0, 0.0, 1.0, 1.0),
(1.0, 0.0, 0.0, 1.0),
]
assert result == expected
def test_rotation(self):
df = DataFrame(randn(5, 5))
# Default rot 0
_, ax = self.plt.subplots()
axes = df.plot(ax=ax)
self._check_ticks_props(axes, xrot=0)
_, ax = self.plt.subplots()
axes = df.plot(rot=30, ax=ax)
self._check_ticks_props(axes, xrot=30)
def test_irregular_datetime(self):
from pandas.plotting._matplotlib.converter import DatetimeConverter
rng = date_range("1/1/2000", "3/1/2000")
rng = rng[[0, 1, 2, 3, 5, 9, 10, 11, 12]]
ser = Series(randn(len(rng)), rng)
_, ax = self.plt.subplots()
ax = ser.plot(ax=ax)
xp = DatetimeConverter.convert(datetime(1999, 1, 1), "", ax)
ax.set_xlim("1/1/1999", "1/1/2001")
assert xp == ax.get_xlim()[0]
def test_unsorted_index_xlim(self):
ser = Series(
[0.0, 1.0, np.nan, 3.0, 4.0, 5.0, 6.0],
index=[1.0, 0.0, 3.0, 2.0, np.nan, 3.0, 2.0],
)
_, ax = self.plt.subplots()
ax = ser.plot(ax=ax)
xmin, xmax = ax.get_xlim()
lines = ax.get_lines()
assert xmin <= np.nanmin(lines[0].get_data(orig=False)[0])
assert xmax >= np.nanmax(lines[0].get_data(orig=False)[0])
@pytest.mark.slow
def test_pie_series(self):
# if sum of values is less than 1.0, pie handle them as rate and draw
# semicircle.
series = Series(
np.random.randint(1, 5), index=["a", "b", "c", "d", "e"], name="YLABEL"
)
ax = _check_plot_works(series.plot.pie)
self._check_text_labels(ax.texts, series.index)
assert ax.get_ylabel() == "YLABEL"
# without wedge labels
ax = _check_plot_works(series.plot.pie, labels=None)
self._check_text_labels(ax.texts, [""] * 5)
# with less colors than elements
color_args = ["r", "g", "b"]
ax = _check_plot_works(series.plot.pie, colors=color_args)
color_expected = ["r", "g", "b", "r", "g"]
self._check_colors(ax.patches, facecolors=color_expected)
# with labels and colors
labels = ["A", "B", "C", "D", "E"]
color_args = ["r", "g", "b", "c", "m"]
ax = _check_plot_works(series.plot.pie, labels=labels, colors=color_args)
self._check_text_labels(ax.texts, labels)
self._check_colors(ax.patches, facecolors=color_args)
# with autopct and fontsize
ax = _check_plot_works(
series.plot.pie, colors=color_args, autopct="%.2f", fontsize=7
)
pcts = [f"{s*100:.2f}" for s in series.values / float(series.sum())]
expected_texts = list(chain.from_iterable(zip(series.index, pcts)))
self._check_text_labels(ax.texts, expected_texts)
for t in ax.texts:
assert t.get_fontsize() == 7
# includes negative value
with pytest.raises(ValueError):
series = Series([1, 2, 0, 4, -1], index=["a", "b", "c", "d", "e"])
series.plot.pie()
# includes nan
series = Series([1, 2, np.nan, 4], index=["a", "b", "c", "d"], name="YLABEL")
ax = _check_plot_works(series.plot.pie)
self._check_text_labels(ax.texts, ["a", "b", "", "d"])
def test_pie_nan(self):
s = Series([1, np.nan, 1, 1])
_, ax = self.plt.subplots()
ax = s.plot.pie(legend=True, ax=ax)
expected = ["0", "", "2", "3"]
result = [x.get_text() for x in ax.texts]
assert result == expected
@pytest.mark.slow
def test_hist_df_kwargs(self):
df = DataFrame(np.random.randn(10, 2))
_, ax = self.plt.subplots()
ax = df.plot.hist(bins=5, ax=ax)
assert len(ax.patches) == 10
@pytest.mark.slow
def test_hist_df_with_nonnumerics(self):
# GH 9853
with tm.RNGContext(1):
df = DataFrame(np.random.randn(10, 4), columns=["A", "B", "C", "D"])
df["E"] = ["x", "y"] * 5
_, ax = self.plt.subplots()
ax = df.plot.hist(bins=5, ax=ax)
assert len(ax.patches) == 20
_, ax = self.plt.subplots()
ax = df.plot.hist(ax=ax) # bins=10
assert len(ax.patches) == 40
@pytest.mark.slow
def test_hist_legacy(self):
_check_plot_works(self.ts.hist)
_check_plot_works(self.ts.hist, grid=False)
_check_plot_works(self.ts.hist, figsize=(8, 10))
# _check_plot_works adds an ax so catch warning. see GH #13188
with tm.assert_produces_warning(UserWarning):
_check_plot_works(self.ts.hist, by=self.ts.index.month)
with tm.assert_produces_warning(UserWarning):
_check_plot_works(self.ts.hist, by=self.ts.index.month, bins=5)
fig, ax = self.plt.subplots(1, 1)
_check_plot_works(self.ts.hist, ax=ax)
_check_plot_works(self.ts.hist, ax=ax, figure=fig)
_check_plot_works(self.ts.hist, figure=fig)
tm.close()
fig, (ax1, ax2) = self.plt.subplots(1, 2)
_check_plot_works(self.ts.hist, figure=fig, ax=ax1)
_check_plot_works(self.ts.hist, figure=fig, ax=ax2)
with pytest.raises(ValueError):
self.ts.hist(by=self.ts.index, figure=fig)
@pytest.mark.slow
def test_hist_bins_legacy(self):
df = DataFrame(np.random.randn(10, 2))
ax = df.hist(bins=2)[0][0]
assert len(ax.patches) == 2
@pytest.mark.slow
def test_hist_layout(self):
df = self.hist_df
with pytest.raises(ValueError):
df.height.hist(layout=(1, 1))
with pytest.raises(ValueError):
df.height.hist(layout=[1, 1])
@pytest.mark.slow
def test_hist_layout_with_by(self):
df = self.hist_df
# _check_plot_works adds an ax so catch warning. see GH #13188
with tm.assert_produces_warning(UserWarning):
axes = _check_plot_works(df.height.hist, by=df.gender, layout=(2, 1))
self._check_axes_shape(axes, axes_num=2, layout=(2, 1))
with tm.assert_produces_warning(UserWarning):
axes = _check_plot_works(df.height.hist, by=df.gender, layout=(3, -1))
self._check_axes_shape(axes, axes_num=2, layout=(3, 1))
with tm.assert_produces_warning(UserWarning):
axes = _check_plot_works(df.height.hist, by=df.category, layout=(4, 1))
self._check_axes_shape(axes, axes_num=4, layout=(4, 1))
with tm.assert_produces_warning(UserWarning):
axes = _check_plot_works(df.height.hist, by=df.category, layout=(2, -1))
self._check_axes_shape(axes, axes_num=4, layout=(2, 2))
with tm.assert_produces_warning(UserWarning):
axes = _check_plot_works(df.height.hist, by=df.category, layout=(3, -1))
self._check_axes_shape(axes, axes_num=4, layout=(3, 2))
with tm.assert_produces_warning(UserWarning):
axes = _check_plot_works(df.height.hist, by=df.category, layout=(-1, 4))
self._check_axes_shape(axes, axes_num=4, layout=(1, 4))
with tm.assert_produces_warning(UserWarning):
axes = _check_plot_works(df.height.hist, by=df.classroom, layout=(2, 2))
self._check_axes_shape(axes, axes_num=3, layout=(2, 2))
axes = df.height.hist(by=df.category, layout=(4, 2), figsize=(12, 7))
self._check_axes_shape(axes, axes_num=4, layout=(4, 2), figsize=(12, 7))
@pytest.mark.slow
def test_hist_no_overlap(self):
from matplotlib.pyplot import gcf, subplot
x = Series(randn(2))
y = Series(randn(2))
subplot(121)
x.hist()
subplot(122)
y.hist()
fig = gcf()
axes = fig.axes
assert len(axes) == 2
@pytest.mark.slow
def test_hist_secondary_legend(self):
# GH 9610
df = DataFrame(np.random.randn(30, 4), columns=list("abcd"))
# primary -> secondary
_, ax = self.plt.subplots()
ax = df["a"].plot.hist(legend=True, ax=ax)
df["b"].plot.hist(ax=ax, legend=True, secondary_y=True)
# both legends are dran on left ax
# left and right axis must be visible
self._check_legend_labels(ax, labels=["a", "b (right)"])
assert ax.get_yaxis().get_visible()
assert ax.right_ax.get_yaxis().get_visible()
tm.close()
# secondary -> secondary
_, ax = self.plt.subplots()
ax = df["a"].plot.hist(legend=True, secondary_y=True, ax=ax)
df["b"].plot.hist(ax=ax, legend=True, secondary_y=True)
# both legends are draw on left ax
# left axis must be invisible, right axis must be visible
self._check_legend_labels(ax.left_ax, labels=["a (right)", "b (right)"])
assert not ax.left_ax.get_yaxis().get_visible()
assert ax.get_yaxis().get_visible()
tm.close()
# secondary -> primary
_, ax = self.plt.subplots()
ax = df["a"].plot.hist(legend=True, secondary_y=True, ax=ax)
# right axes is returned
df["b"].plot.hist(ax=ax, legend=True)
# both legends are draw on left ax
# left and right axis must be visible
self._check_legend_labels(ax.left_ax, labels=["a (right)", "b"])
assert ax.left_ax.get_yaxis().get_visible()
assert ax.get_yaxis().get_visible()
tm.close()
@pytest.mark.slow
def test_df_series_secondary_legend(self):
# GH 9779
df = DataFrame(np.random.randn(30, 3), columns=list("abc"))
s = Series(np.random.randn(30), name="x")
# primary -> secondary (without passing ax)
_, ax = self.plt.subplots()
ax = df.plot(ax=ax)
s.plot(legend=True, secondary_y=True, ax=ax)
# both legends are dran on left ax
# left and right axis must be visible
self._check_legend_labels(ax, labels=["a", "b", "c", "x (right)"])
assert ax.get_yaxis().get_visible()
assert ax.right_ax.get_yaxis().get_visible()
tm.close()
# primary -> secondary (with passing ax)
_, ax = self.plt.subplots()
ax = df.plot(ax=ax)
s.plot(ax=ax, legend=True, secondary_y=True)
# both legends are dran on left ax
# left and right axis must be visible
self._check_legend_labels(ax, labels=["a", "b", "c", "x (right)"])
assert ax.get_yaxis().get_visible()
assert ax.right_ax.get_yaxis().get_visible()
tm.close()
# secondary -> secondary (without passing ax)
_, ax = self.plt.subplots()
ax = df.plot(secondary_y=True, ax=ax)
s.plot(legend=True, secondary_y=True, ax=ax)
# both legends are dran on left ax
# left axis must be invisible and right axis must be visible
expected = ["a (right)", "b (right)", "c (right)", "x (right)"]
self._check_legend_labels(ax.left_ax, labels=expected)
assert not ax.left_ax.get_yaxis().get_visible()
assert ax.get_yaxis().get_visible()
tm.close()
# secondary -> secondary (with passing ax)
_, ax = self.plt.subplots()
ax = df.plot(secondary_y=True, ax=ax)
s.plot(ax=ax, legend=True, secondary_y=True)
# both legends are dran on left ax
# left axis must be invisible and right axis must be visible
expected = ["a (right)", "b (right)", "c (right)", "x (right)"]
self._check_legend_labels(ax.left_ax, expected)
assert not ax.left_ax.get_yaxis().get_visible()
assert ax.get_yaxis().get_visible()
tm.close()
# secondary -> secondary (with passing ax)
_, ax = self.plt.subplots()
ax = df.plot(secondary_y=True, mark_right=False, ax=ax)
s.plot(ax=ax, legend=True, secondary_y=True)
# both legends are dran on left ax
# left axis must be invisible and right axis must be visible
expected = ["a", "b", "c", "x (right)"]
self._check_legend_labels(ax.left_ax, expected)
assert not ax.left_ax.get_yaxis().get_visible()
assert ax.get_yaxis().get_visible()
tm.close()
@pytest.mark.slow
@pytest.mark.parametrize(
"input_logy, expected_scale", [(True, "log"), ("sym", "symlog")]
)
def test_secondary_logy(self, input_logy, expected_scale):
# GH 25545
s1 = Series(np.random.randn(30))
s2 = Series(np.random.randn(30))
# GH 24980
ax1 = s1.plot(logy=input_logy)
ax2 = s2.plot(secondary_y=True, logy=input_logy)
assert ax1.get_yscale() == expected_scale
assert ax2.get_yscale() == expected_scale
@pytest.mark.slow
def test_plot_fails_with_dupe_color_and_style(self):
x = Series(randn(2))
with pytest.raises(ValueError):
_, ax = self.plt.subplots()
x.plot(style="k--", color="k", ax=ax)
@pytest.mark.slow
@td.skip_if_no_scipy
def test_hist_kde(self):
_, ax = self.plt.subplots()
ax = self.ts.plot.hist(logy=True, ax=ax)
self._check_ax_scales(ax, yaxis="log")
xlabels = ax.get_xticklabels()
# ticks are values, thus ticklabels are blank
self._check_text_labels(xlabels, [""] * len(xlabels))
ylabels = ax.get_yticklabels()
self._check_text_labels(ylabels, [""] * len(ylabels))
_check_plot_works(self.ts.plot.kde)
_check_plot_works(self.ts.plot.density)
_, ax = self.plt.subplots()
ax = self.ts.plot.kde(logy=True, ax=ax)
self._check_ax_scales(ax, yaxis="log")
xlabels = ax.get_xticklabels()
self._check_text_labels(xlabels, [""] * len(xlabels))
ylabels = ax.get_yticklabels()
self._check_text_labels(ylabels, [""] * len(ylabels))
@pytest.mark.slow
@td.skip_if_no_scipy
def test_kde_kwargs(self):
sample_points = np.linspace(-100, 100, 20)
_check_plot_works(self.ts.plot.kde, bw_method="scott", ind=20)
_check_plot_works(self.ts.plot.kde, bw_method=None, ind=20)
_check_plot_works(self.ts.plot.kde, bw_method=None, ind=np.int_(20))
_check_plot_works(self.ts.plot.kde, bw_method=0.5, ind=sample_points)
_check_plot_works(self.ts.plot.density, bw_method=0.5, ind=sample_points)
_, ax = self.plt.subplots()
ax = self.ts.plot.kde(logy=True, bw_method=0.5, ind=sample_points, ax=ax)
self._check_ax_scales(ax, yaxis="log")
self._check_text_labels(ax.yaxis.get_label(), "Density")
@pytest.mark.slow
@td.skip_if_no_scipy
def test_kde_missing_vals(self):
s = Series(np.random.uniform(size=50))
s[0] = np.nan
axes = _check_plot_works(s.plot.kde)
# gh-14821: check if the values have any missing values
assert any(~np.isnan(axes.lines[0].get_xdata()))
@pytest.mark.slow
def test_hist_kwargs(self):
_, ax = self.plt.subplots()
ax = self.ts.plot.hist(bins=5, ax=ax)
assert len(ax.patches) == 5
self._check_text_labels(ax.yaxis.get_label(), "Frequency")
tm.close()
_, ax = self.plt.subplots()
ax = self.ts.plot.hist(orientation="horizontal", ax=ax)
self._check_text_labels(ax.xaxis.get_label(), "Frequency")
tm.close()
_, ax = self.plt.subplots()
ax = self.ts.plot.hist(align="left", stacked=True, ax=ax)
tm.close()
@pytest.mark.slow
@td.skip_if_no_scipy
def test_hist_kde_color(self):
_, ax = self.plt.subplots()
ax = self.ts.plot.hist(logy=True, bins=10, color="b", ax=ax)
self._check_ax_scales(ax, yaxis="log")
assert len(ax.patches) == 10
self._check_colors(ax.patches, facecolors=["b"] * 10)
_, ax = self.plt.subplots()
ax = self.ts.plot.kde(logy=True, color="r", ax=ax)
self._check_ax_scales(ax, yaxis="log")
lines = ax.get_lines()
assert len(lines) == 1
self._check_colors(lines, ["r"])
@pytest.mark.slow
def test_boxplot_series(self):
_, ax = self.plt.subplots()
ax = self.ts.plot.box(logy=True, ax=ax)
self._check_ax_scales(ax, yaxis="log")
xlabels = ax.get_xticklabels()
self._check_text_labels(xlabels, [self.ts.name])
ylabels = ax.get_yticklabels()
self._check_text_labels(ylabels, [""] * len(ylabels))
@pytest.mark.slow
def test_kind_both_ways(self):
s = Series(range(3))
kinds = (
plotting.PlotAccessor._common_kinds + plotting.PlotAccessor._series_kinds
)
for kind in kinds:
_, ax = self.plt.subplots()
s.plot(kind=kind, ax=ax)
self.plt.close()
_, ax = self.plt.subplots()
getattr(s.plot, kind)()
self.plt.close()
@pytest.mark.slow
def test_invalid_plot_data(self):
s = Series(list("abcd"))
_, ax = self.plt.subplots()
for kind in plotting.PlotAccessor._common_kinds:
msg = "no numeric data to plot"
with pytest.raises(TypeError, match=msg):
s.plot(kind=kind, ax=ax)
@pytest.mark.slow
def test_valid_object_plot(self):
s = Series(range(10), dtype=object)
for kind in plotting.PlotAccessor._common_kinds:
_check_plot_works(s.plot, kind=kind)
def test_partially_invalid_plot_data(self):
s = Series(["a", "b", 1.0, 2])
_, ax = self.plt.subplots()
for kind in plotting.PlotAccessor._common_kinds:
msg = "no numeric data to plot"
with pytest.raises(TypeError, match=msg):
s.plot(kind=kind, ax=ax)
def test_invalid_kind(self):
s = Series([1, 2])
with pytest.raises(ValueError):
s.plot(kind="aasdf")
@pytest.mark.slow
def test_dup_datetime_index_plot(self):
dr1 = date_range("1/1/2009", periods=4)
dr2 = date_range("1/2/2009", periods=4)
index = dr1.append(dr2)
values = randn(index.size)
s = Series(values, index=index)
_check_plot_works(s.plot)
def test_errorbar_asymmetrical(self):
# GH9536
s = Series(np.arange(10), name="x")
err = np.random.rand(2, 10)
ax = s.plot(yerr=err, xerr=err)
result = np.vstack([i.vertices[:, 1] for i in ax.collections[1].get_paths()])
expected = (err.T * np.array([-1, 1])) + s.to_numpy().reshape(-1, 1)
tm.assert_numpy_array_equal(result, expected)
msg = (
"Asymmetrical error bars should be provided "
f"with the shape \\(2, {len(s)}\\)"
)
with pytest.raises(ValueError, match=msg):
s.plot(yerr=np.random.rand(2, 11))
tm.close()
@pytest.mark.slow
def test_errorbar_plot(self):
s = Series(np.arange(10), name="x")
s_err = np.random.randn(10)
d_err = DataFrame(randn(10, 2), index=s.index, columns=["x", "y"])
# test line and bar plots
kinds = ["line", "bar"]
for kind in kinds:
ax = _check_plot_works(s.plot, yerr=Series(s_err), kind=kind)
self._check_has_errorbars(ax, xerr=0, yerr=1)
ax = _check_plot_works(s.plot, yerr=s_err, kind=kind)
self._check_has_errorbars(ax, xerr=0, yerr=1)
ax = _check_plot_works(s.plot, yerr=s_err.tolist(), kind=kind)
self._check_has_errorbars(ax, xerr=0, yerr=1)
ax = _check_plot_works(s.plot, yerr=d_err, kind=kind)
self._check_has_errorbars(ax, xerr=0, yerr=1)
ax = _check_plot_works(s.plot, xerr=0.2, yerr=0.2, kind=kind)
self._check_has_errorbars(ax, xerr=1, yerr=1)
ax = _check_plot_works(s.plot, xerr=s_err)
self._check_has_errorbars(ax, xerr=1, yerr=0)
# test time series plotting
ix = date_range("1/1/2000", "1/1/2001", freq="M")
ts = Series(np.arange(12), index=ix, name="x")
ts_err = Series(np.random.randn(12), index=ix)
td_err = DataFrame(randn(12, 2), index=ix, columns=["x", "y"])
ax = _check_plot_works(ts.plot, yerr=ts_err)
self._check_has_errorbars(ax, xerr=0, yerr=1)
ax = _check_plot_works(ts.plot, yerr=td_err)
self._check_has_errorbars(ax, xerr=0, yerr=1)
# check incorrect lengths and types
with pytest.raises(ValueError):
s.plot(yerr=np.arange(11))
s_err = ["zzz"] * 10
with pytest.raises(TypeError):
s.plot(yerr=s_err)
def test_table(self):
_check_plot_works(self.series.plot, table=True)
_check_plot_works(self.series.plot, table=self.series)
@pytest.mark.slow
def test_series_grid_settings(self):
# Make sure plot defaults to rcParams['axes.grid'] setting, GH 9792
self._check_grid_settings(
Series([1, 2, 3]),
plotting.PlotAccessor._series_kinds + plotting.PlotAccessor._common_kinds,
)
@pytest.mark.slow
def test_standard_colors(self):
from pandas.plotting._matplotlib.style import _get_standard_colors
for c in ["r", "red", "green", "#FF0000"]:
result = _get_standard_colors(1, color=c)
assert result == [c]
result = _get_standard_colors(1, color=[c])
assert result == [c]
result = _get_standard_colors(3, color=c)
assert result == [c] * 3
result = _get_standard_colors(3, color=[c])
assert result == [c] * 3
@pytest.mark.slow
def test_standard_colors_all(self):
import matplotlib.colors as colors
from pandas.plotting._matplotlib.style import _get_standard_colors
# multiple colors like mediumaquamarine
for c in colors.cnames:
result = _get_standard_colors(num_colors=1, color=c)
assert result == [c]
result = _get_standard_colors(num_colors=1, color=[c])
assert result == [c]
result = _get_standard_colors(num_colors=3, color=c)
assert result == [c] * 3
result = _get_standard_colors(num_colors=3, color=[c])
assert result == [c] * 3
# single letter colors like k
for c in colors.ColorConverter.colors:
result = _get_standard_colors(num_colors=1, color=c)
assert result == [c]
result = _get_standard_colors(num_colors=1, color=[c])
assert result == [c]
result = _get_standard_colors(num_colors=3, color=c)
assert result == [c] * 3
result = _get_standard_colors(num_colors=3, color=[c])
assert result == [c] * 3
def test_series_plot_color_kwargs(self):
# GH1890
_, ax = self.plt.subplots()
ax = Series(np.arange(12) + 1).plot(color="green", ax=ax)
self._check_colors(ax.get_lines(), linecolors=["green"])
def test_time_series_plot_color_kwargs(self):
# #1890
_, ax = self.plt.subplots()
ax = Series(np.arange(12) + 1, index=date_range("1/1/2000", periods=12)).plot(
color="green", ax=ax
)
self._check_colors(ax.get_lines(), linecolors=["green"])
def test_time_series_plot_color_with_empty_kwargs(self):
import matplotlib as mpl
def_colors = self._unpack_cycler(mpl.rcParams)
index = date_range("1/1/2000", periods=12)
s = Series(np.arange(1, 13), index=index)
ncolors = 3
_, ax = self.plt.subplots()
for i in range(ncolors):
ax = s.plot(ax=ax)
self._check_colors(ax.get_lines(), linecolors=def_colors[:ncolors])
def test_xticklabels(self):
# GH11529
s = Series(np.arange(10), index=[f"P{i:02d}" for i in range(10)])
_, ax = self.plt.subplots()
ax = s.plot(xticks=[0, 3, 5, 9], ax=ax)
exp = [f"P{i:02d}" for i in [0, 3, 5, 9]]
self._check_text_labels(ax.get_xticklabels(), exp)
def test_xtick_barPlot(self):
# GH28172
s = pd.Series(range(10), index=[f"P{i:02d}" for i in range(10)])
ax = s.plot.bar(xticks=range(0, 11, 2))
exp = np.array(list(range(0, 11, 2)))
tm.assert_numpy_array_equal(exp, ax.get_xticks())
def test_custom_business_day_freq(self):
# GH7222
from pandas.tseries.offsets import CustomBusinessDay
s = Series(
range(100, 121),
index=pd.bdate_range(
start="2014-05-01",
end="2014-06-01",
freq=CustomBusinessDay(holidays=["2014-05-26"]),
),
)
_check_plot_works(s.plot)
@pytest.mark.xfail
def test_plot_accessor_updates_on_inplace(self):
s = Series([1, 2, 3, 4])
_, ax = self.plt.subplots()
ax = s.plot(ax=ax)
before = ax.xaxis.get_ticklocs()
s.drop([0, 1], inplace=True)
_, ax = self.plt.subplots()
after = ax.xaxis.get_ticklocs()
tm.assert_numpy_array_equal(before, after)
@pytest.mark.parametrize("kind", ["line", "area"])
def test_plot_xlim_for_series(self, kind):
# test if xlim is also correctly plotted in Series for line and area
# GH 27686
s = Series([2, 3])
_, ax = self.plt.subplots()
s.plot(kind=kind, ax=ax)
xlims = ax.get_xlim()
assert xlims[0] < 0
assert xlims[1] > 1
def test_plot_no_rows(self):
# GH 27758
df = pd.Series(dtype=int)
assert df.empty
ax = df.plot()
assert len(ax.get_lines()) == 1
line = ax.get_lines()[0]
assert len(line.get_xdata()) == 0
assert len(line.get_ydata()) == 0
def test_plot_no_numeric_data(self):
df = pd.Series(["a", "b", "c"])
with pytest.raises(TypeError):
df.plot()
def test_style_single_ok(self):
s = pd.Series([1, 2])
ax = s.plot(style="s", color="C3")
assert ax.lines[0].get_color() == ["C3"]
@pytest.mark.parametrize(
"index_name, old_label, new_label",
[(None, "", "new"), ("old", "old", "new"), (None, "", "")],
)
@pytest.mark.parametrize("kind", ["line", "area", "bar"])
def test_xlabel_ylabel_series(self, kind, index_name, old_label, new_label):
# GH 9093
ser = pd.Series([1, 2, 3, 4])
ser.index.name = index_name
# default is the ylabel is not shown and xlabel is index name
ax = ser.plot(kind=kind)
assert ax.get_ylabel() == ""
assert ax.get_xlabel() == old_label
# old xlabel will be overriden and assigned ylabel will be used as ylabel
ax = ser.plot(kind=kind, ylabel=new_label, xlabel=new_label)
assert ax.get_ylabel() == new_label
assert ax.get_xlabel() == new_label