1903 lines
75 KiB
Python
1903 lines
75 KiB
Python
"""
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Classes to support contour plotting and labelling for the Axes class.
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"""
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from contextlib import ExitStack
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import functools
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import math
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from numbers import Integral
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import numpy as np
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from numpy import ma
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import matplotlib as mpl
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from matplotlib import _api, _docstring
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from matplotlib.backend_bases import MouseButton
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from matplotlib.lines import Line2D
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from matplotlib.path import Path
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from matplotlib.text import Text
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import matplotlib.ticker as ticker
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import matplotlib.cm as cm
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import matplotlib.colors as mcolors
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import matplotlib.collections as mcoll
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import matplotlib.font_manager as font_manager
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import matplotlib.cbook as cbook
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import matplotlib.patches as mpatches
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import matplotlib.transforms as mtransforms
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@_api.deprecated("3.7", alternative="Text.set_transform_rotates_text")
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class ClabelText(Text):
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"""
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Unlike the ordinary text, the get_rotation returns an updated
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angle in the pixel coordinate assuming that the input rotation is
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an angle in data coordinate (or whatever transform set).
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"""
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def get_rotation(self):
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new_angle, = self.get_transform().transform_angles(
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[super().get_rotation()], [self.get_position()])
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return new_angle
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def _contour_labeler_event_handler(cs, inline, inline_spacing, event):
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canvas = cs.axes.figure.canvas
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is_button = event.name == "button_press_event"
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is_key = event.name == "key_press_event"
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# Quit (even if not in infinite mode; this is consistent with
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# MATLAB and sometimes quite useful, but will require the user to
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# test how many points were actually returned before using data).
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if (is_button and event.button == MouseButton.MIDDLE
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or is_key and event.key in ["escape", "enter"]):
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canvas.stop_event_loop()
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# Pop last click.
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elif (is_button and event.button == MouseButton.RIGHT
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or is_key and event.key in ["backspace", "delete"]):
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# Unfortunately, if one is doing inline labels, then there is currently
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# no way to fix the broken contour - once humpty-dumpty is broken, he
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# can't be put back together. In inline mode, this does nothing.
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if not inline:
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cs.pop_label()
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canvas.draw()
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# Add new click.
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elif (is_button and event.button == MouseButton.LEFT
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# On macOS/gtk, some keys return None.
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or is_key and event.key is not None):
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if cs.axes.contains(event)[0]:
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cs.add_label_near(event.x, event.y, transform=False,
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inline=inline, inline_spacing=inline_spacing)
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canvas.draw()
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class ContourLabeler:
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"""Mixin to provide labelling capability to `.ContourSet`."""
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def clabel(self, levels=None, *,
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fontsize=None, inline=True, inline_spacing=5, fmt=None,
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colors=None, use_clabeltext=False, manual=False,
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rightside_up=True, zorder=None):
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"""
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Label a contour plot.
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Adds labels to line contours in this `.ContourSet` (which inherits from
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this mixin class).
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Parameters
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----------
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levels : array-like, optional
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A list of level values, that should be labeled. The list must be
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a subset of ``cs.levels``. If not given, all levels are labeled.
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fontsize : str or float, default: :rc:`font.size`
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Size in points or relative size e.g., 'smaller', 'x-large'.
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See `.Text.set_size` for accepted string values.
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colors : color or colors or None, default: None
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The label colors:
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- If *None*, the color of each label matches the color of
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the corresponding contour.
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- If one string color, e.g., *colors* = 'r' or *colors* =
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'red', all labels will be plotted in this color.
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- If a tuple of colors (string, float, RGB, etc), different labels
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will be plotted in different colors in the order specified.
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inline : bool, default: True
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If ``True`` the underlying contour is removed where the label is
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placed.
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inline_spacing : float, default: 5
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Space in pixels to leave on each side of label when placing inline.
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This spacing will be exact for labels at locations where the
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contour is straight, less so for labels on curved contours.
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fmt : `.Formatter` or str or callable or dict, optional
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How the levels are formatted:
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- If a `.Formatter`, it is used to format all levels at once, using
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its `.Formatter.format_ticks` method.
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- If a str, it is interpreted as a %-style format string.
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- If a callable, it is called with one level at a time and should
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return the corresponding label.
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- If a dict, it should directly map levels to labels.
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The default is to use a standard `.ScalarFormatter`.
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manual : bool or iterable, default: False
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If ``True``, contour labels will be placed manually using
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mouse clicks. Click the first button near a contour to
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add a label, click the second button (or potentially both
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mouse buttons at once) to finish adding labels. The third
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button can be used to remove the last label added, but
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only if labels are not inline. Alternatively, the keyboard
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can be used to select label locations (enter to end label
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placement, delete or backspace act like the third mouse button,
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and any other key will select a label location).
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*manual* can also be an iterable object of (x, y) tuples.
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Contour labels will be created as if mouse is clicked at each
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(x, y) position.
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rightside_up : bool, default: True
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If ``True``, label rotations will always be plus
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or minus 90 degrees from level.
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use_clabeltext : bool, default: False
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If ``True``, use `.Text.set_transform_rotates_text` to ensure that
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label rotation is updated whenever the axes aspect changes.
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zorder : float or None, default: ``(2 + contour.get_zorder())``
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zorder of the contour labels.
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Returns
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-------
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labels
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A list of `.Text` instances for the labels.
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"""
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# clabel basically takes the input arguments and uses them to
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# add a list of "label specific" attributes to the ContourSet
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# object. These attributes are all of the form label* and names
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# should be fairly self explanatory.
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#
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# Once these attributes are set, clabel passes control to the
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# labels method (case of automatic label placement) or
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# `BlockingContourLabeler` (case of manual label placement).
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if fmt is None:
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fmt = ticker.ScalarFormatter(useOffset=False)
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fmt.create_dummy_axis()
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self.labelFmt = fmt
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self._use_clabeltext = use_clabeltext
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# Detect if manual selection is desired and remove from argument list.
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self.labelManual = manual
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self.rightside_up = rightside_up
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self._clabel_zorder = 2 + self.get_zorder() if zorder is None else zorder
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if levels is None:
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levels = self.levels
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indices = list(range(len(self.cvalues)))
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else:
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levlabs = list(levels)
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indices, levels = [], []
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for i, lev in enumerate(self.levels):
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if lev in levlabs:
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indices.append(i)
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levels.append(lev)
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if len(levels) < len(levlabs):
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raise ValueError(f"Specified levels {levlabs} don't match "
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f"available levels {self.levels}")
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self.labelLevelList = levels
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self.labelIndiceList = indices
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self._label_font_props = font_manager.FontProperties(size=fontsize)
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if colors is None:
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self.labelMappable = self
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self.labelCValueList = np.take(self.cvalues, self.labelIndiceList)
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else:
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cmap = mcolors.ListedColormap(colors, N=len(self.labelLevelList))
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self.labelCValueList = list(range(len(self.labelLevelList)))
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self.labelMappable = cm.ScalarMappable(cmap=cmap,
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norm=mcolors.NoNorm())
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self.labelXYs = []
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if np.iterable(manual):
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for x, y in manual:
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self.add_label_near(x, y, inline, inline_spacing)
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elif manual:
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print('Select label locations manually using first mouse button.')
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print('End manual selection with second mouse button.')
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if not inline:
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print('Remove last label by clicking third mouse button.')
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mpl._blocking_input.blocking_input_loop(
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self.axes.figure, ["button_press_event", "key_press_event"],
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timeout=-1, handler=functools.partial(
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_contour_labeler_event_handler,
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self, inline, inline_spacing))
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else:
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self.labels(inline, inline_spacing)
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return cbook.silent_list('text.Text', self.labelTexts)
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@_api.deprecated("3.7", alternative="cs.labelTexts[0].get_font()")
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@property
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def labelFontProps(self):
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return self._label_font_props
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@_api.deprecated("3.7", alternative=(
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"[cs.labelTexts[0].get_font().get_size()] * len(cs.labelLevelList)"))
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@property
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def labelFontSizeList(self):
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return [self._label_font_props.get_size()] * len(self.labelLevelList)
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@_api.deprecated("3.7", alternative="cs.labelTexts")
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@property
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def labelTextsList(self):
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return cbook.silent_list('text.Text', self.labelTexts)
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def print_label(self, linecontour, labelwidth):
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"""Return whether a contour is long enough to hold a label."""
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return (len(linecontour) > 10 * labelwidth
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or (len(linecontour)
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and (np.ptp(linecontour, axis=0) > 1.2 * labelwidth).any()))
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def too_close(self, x, y, lw):
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"""Return whether a label is already near this location."""
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thresh = (1.2 * lw) ** 2
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return any((x - loc[0]) ** 2 + (y - loc[1]) ** 2 < thresh
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for loc in self.labelXYs)
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def _get_nth_label_width(self, nth):
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"""Return the width of the *nth* label, in pixels."""
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fig = self.axes.figure
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renderer = fig._get_renderer()
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return (Text(0, 0,
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self.get_text(self.labelLevelList[nth], self.labelFmt),
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figure=fig, fontproperties=self._label_font_props)
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.get_window_extent(renderer).width)
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@_api.deprecated("3.7", alternative="Artist.set")
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def set_label_props(self, label, text, color):
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"""Set the label properties - color, fontsize, text."""
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label.set_text(text)
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label.set_color(color)
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label.set_fontproperties(self._label_font_props)
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label.set_clip_box(self.axes.bbox)
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def get_text(self, lev, fmt):
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"""Get the text of the label."""
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if isinstance(lev, str):
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return lev
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elif isinstance(fmt, dict):
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return fmt.get(lev, '%1.3f')
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elif callable(getattr(fmt, "format_ticks", None)):
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return fmt.format_ticks([*self.labelLevelList, lev])[-1]
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elif callable(fmt):
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return fmt(lev)
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else:
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return fmt % lev
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def locate_label(self, linecontour, labelwidth):
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"""
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Find good place to draw a label (relatively flat part of the contour).
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"""
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ctr_size = len(linecontour)
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n_blocks = int(np.ceil(ctr_size / labelwidth)) if labelwidth > 1 else 1
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block_size = ctr_size if n_blocks == 1 else int(labelwidth)
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# Split contour into blocks of length ``block_size``, filling the last
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# block by cycling the contour start (per `np.resize` semantics). (Due
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# to cycling, the index returned is taken modulo ctr_size.)
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xx = np.resize(linecontour[:, 0], (n_blocks, block_size))
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yy = np.resize(linecontour[:, 1], (n_blocks, block_size))
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yfirst = yy[:, :1]
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ylast = yy[:, -1:]
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xfirst = xx[:, :1]
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xlast = xx[:, -1:]
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s = (yfirst - yy) * (xlast - xfirst) - (xfirst - xx) * (ylast - yfirst)
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l = np.hypot(xlast - xfirst, ylast - yfirst)
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# Ignore warning that divide by zero throws, as this is a valid option
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with np.errstate(divide='ignore', invalid='ignore'):
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distances = (abs(s) / l).sum(axis=-1)
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# Labels are drawn in the middle of the block (``hbsize``) where the
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# contour is the closest (per ``distances``) to a straight line, but
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# not `too_close()` to a preexisting label.
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hbsize = block_size // 2
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adist = np.argsort(distances)
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# If all candidates are `too_close()`, go back to the straightest part
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# (``adist[0]``).
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for idx in np.append(adist, adist[0]):
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x, y = xx[idx, hbsize], yy[idx, hbsize]
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if not self.too_close(x, y, labelwidth):
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break
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return x, y, (idx * block_size + hbsize) % ctr_size
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def _split_path_and_get_label_rotation(self, path, idx, screen_pos, lw, spacing=5):
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"""
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Prepare for insertion of a label at index *idx* of *path*.
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Parameters
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----------
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path : Path
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The path where the label will be inserted, in data space.
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idx : int
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The vertex index after which the label will be inserted.
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screen_pos : (float, float)
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The position where the label will be inserted, in screen space.
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lw : float
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The label width, in screen space.
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spacing : float
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Extra spacing around the label, in screen space.
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Returns
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-------
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path : Path
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The path, broken so that the label can be drawn over it.
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angle : float
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The rotation of the label.
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Notes
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-----
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Both tasks are done together to avoid calculating path lengths multiple times,
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which is relatively costly.
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The method used here involves computing the path length along the contour in
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pixel coordinates and then looking (label width / 2) away from central point to
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determine rotation and then to break contour if desired. The extra spacing is
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taken into account when breaking the path, but not when computing the angle.
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"""
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if hasattr(self, "_old_style_split_collections"):
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vis = False
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for coll in self._old_style_split_collections:
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vis |= coll.get_visible()
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coll.remove()
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self.set_visible(vis)
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del self._old_style_split_collections # Invalidate them.
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xys = path.vertices
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codes = path.codes
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# Insert a vertex at idx/pos (converting back to data space), if there isn't yet
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# a vertex there. With infinite precision one could also always insert the
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# extra vertex (it will get masked out by the label below anyways), but floating
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# point inaccuracies (the point can have undergone a data->screen->data
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# transform loop) can slightly shift the point and e.g. shift the angle computed
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# below from exactly zero to nonzero.
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pos = self.get_transform().inverted().transform(screen_pos)
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if not np.allclose(pos, xys[idx]):
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xys = np.insert(xys, idx, pos, axis=0)
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codes = np.insert(codes, idx, Path.LINETO)
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# Find the connected component where the label will be inserted. Note that a
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# path always starts with a MOVETO, and we consider there's an implicit
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# MOVETO (closing the last path) at the end.
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movetos = (codes == Path.MOVETO).nonzero()[0]
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start = movetos[movetos <= idx][-1]
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try:
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stop = movetos[movetos > idx][0]
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except IndexError:
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stop = len(codes)
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# Restrict ourselves to the connected component.
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cc_xys = xys[start:stop]
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idx -= start
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# If the path is closed, rotate it s.t. it starts at the label.
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is_closed_path = codes[stop - 1] == Path.CLOSEPOLY
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if is_closed_path:
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cc_xys = np.concatenate([cc_xys[idx:-1], cc_xys[:idx+1]])
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idx = 0
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# Like np.interp, but additionally vectorized over fp.
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def interp_vec(x, xp, fp): return [np.interp(x, xp, col) for col in fp.T]
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# Use cumulative path lengths ("cpl") as curvilinear coordinate along contour.
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screen_xys = self.get_transform().transform(cc_xys)
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path_cpls = np.insert(
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np.cumsum(np.hypot(*np.diff(screen_xys, axis=0).T)), 0, 0)
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path_cpls -= path_cpls[idx]
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# Use linear interpolation to get end coordinates of label.
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target_cpls = np.array([-lw/2, lw/2])
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if is_closed_path: # For closed paths, target from the other end.
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target_cpls[0] += (path_cpls[-1] - path_cpls[0])
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(sx0, sx1), (sy0, sy1) = interp_vec(target_cpls, path_cpls, screen_xys)
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angle = np.rad2deg(np.arctan2(sy1 - sy0, sx1 - sx0)) # Screen space.
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if self.rightside_up: # Fix angle so text is never upside-down
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angle = (angle + 90) % 180 - 90
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target_cpls += [-spacing, +spacing] # Expand range by spacing.
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# Get indices near points of interest; use -1 as out of bounds marker.
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i0, i1 = np.interp(target_cpls, path_cpls, range(len(path_cpls)),
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left=-1, right=-1)
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i0 = math.floor(i0)
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i1 = math.ceil(i1)
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(x0, x1), (y0, y1) = interp_vec(target_cpls, path_cpls, cc_xys)
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# Actually break contours (dropping zero-len parts).
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new_xy_blocks = []
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new_code_blocks = []
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if is_closed_path:
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if i0 != -1 and i1 != -1:
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# This is probably wrong in the case that the entire contour would
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# be discarded, but ensures that a valid path is returned and is
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# consistent with behavior of mpl <3.8
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points = cc_xys[i1:i0+1]
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new_xy_blocks.extend([[(x1, y1)], points, [(x0, y0)]])
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nlines = len(points) + 1
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new_code_blocks.extend([[Path.MOVETO], [Path.LINETO] * nlines])
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else:
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if i0 != -1:
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new_xy_blocks.extend([cc_xys[:i0 + 1], [(x0, y0)]])
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new_code_blocks.extend([[Path.MOVETO], [Path.LINETO] * (i0 + 1)])
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if i1 != -1:
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new_xy_blocks.extend([[(x1, y1)], cc_xys[i1:]])
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new_code_blocks.extend([
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[Path.MOVETO], [Path.LINETO] * (len(cc_xys) - i1)])
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# Back to the full path.
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xys = np.concatenate([xys[:start], *new_xy_blocks, xys[stop:]])
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codes = np.concatenate([codes[:start], *new_code_blocks, codes[stop:]])
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return angle, Path(xys, codes)
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@_api.deprecated("3.8")
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def calc_label_rot_and_inline(self, slc, ind, lw, lc=None, spacing=5):
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"""
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Calculate the appropriate label rotation given the linecontour
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coordinates in screen units, the index of the label location and the
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label width.
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|
|
If *lc* is not None or empty, also break contours and compute
|
|
inlining.
|
|
|
|
*spacing* is the empty space to leave around the label, in pixels.
|
|
|
|
Both tasks are done together to avoid calculating path lengths
|
|
multiple times, which is relatively costly.
|
|
|
|
The method used here involves computing the path length along the
|
|
contour in pixel coordinates and then looking approximately (label
|
|
width / 2) away from central point to determine rotation and then to
|
|
break contour if desired.
|
|
"""
|
|
|
|
if lc is None:
|
|
lc = []
|
|
# Half the label width
|
|
hlw = lw / 2.0
|
|
|
|
# Check if closed and, if so, rotate contour so label is at edge
|
|
closed = _is_closed_polygon(slc)
|
|
if closed:
|
|
slc = np.concatenate([slc[ind:-1], slc[:ind + 1]])
|
|
if len(lc): # Rotate lc also if not empty
|
|
lc = np.concatenate([lc[ind:-1], lc[:ind + 1]])
|
|
ind = 0
|
|
|
|
# Calculate path lengths
|
|
pl = np.zeros(slc.shape[0], dtype=float)
|
|
dx = np.diff(slc, axis=0)
|
|
pl[1:] = np.cumsum(np.hypot(dx[:, 0], dx[:, 1]))
|
|
pl = pl - pl[ind]
|
|
|
|
# Use linear interpolation to get points around label
|
|
xi = np.array([-hlw, hlw])
|
|
if closed: # Look at end also for closed contours
|
|
dp = np.array([pl[-1], 0])
|
|
else:
|
|
dp = np.zeros_like(xi)
|
|
|
|
# Get angle of vector between the two ends of the label - must be
|
|
# calculated in pixel space for text rotation to work correctly.
|
|
(dx,), (dy,) = (np.diff(np.interp(dp + xi, pl, slc_col))
|
|
for slc_col in slc.T)
|
|
rotation = np.rad2deg(np.arctan2(dy, dx))
|
|
|
|
if self.rightside_up:
|
|
# Fix angle so text is never upside-down
|
|
rotation = (rotation + 90) % 180 - 90
|
|
|
|
# Break contour if desired
|
|
nlc = []
|
|
if len(lc):
|
|
# Expand range by spacing
|
|
xi = dp + xi + np.array([-spacing, spacing])
|
|
|
|
# Get (integer) indices near points of interest; use -1 as marker
|
|
# for out of bounds.
|
|
I = np.interp(xi, pl, np.arange(len(pl)), left=-1, right=-1)
|
|
I = [np.floor(I[0]).astype(int), np.ceil(I[1]).astype(int)]
|
|
if I[0] != -1:
|
|
xy1 = [np.interp(xi[0], pl, lc_col) for lc_col in lc.T]
|
|
if I[1] != -1:
|
|
xy2 = [np.interp(xi[1], pl, lc_col) for lc_col in lc.T]
|
|
|
|
# Actually break contours
|
|
if closed:
|
|
# This will remove contour if shorter than label
|
|
if all(i != -1 for i in I):
|
|
nlc.append(np.vstack([xy2, lc[I[1]:I[0]+1], xy1]))
|
|
else:
|
|
# These will remove pieces of contour if they have length zero
|
|
if I[0] != -1:
|
|
nlc.append(np.vstack([lc[:I[0]+1], xy1]))
|
|
if I[1] != -1:
|
|
nlc.append(np.vstack([xy2, lc[I[1]:]]))
|
|
|
|
# The current implementation removes contours completely
|
|
# covered by labels. Uncomment line below to keep
|
|
# original contour if this is the preferred behavior.
|
|
# if not len(nlc): nlc = [lc]
|
|
|
|
return rotation, nlc
|
|
|
|
def add_label(self, x, y, rotation, lev, cvalue):
|
|
"""Add contour label without `.Text.set_transform_rotates_text`."""
|
|
data_x, data_y = self.axes.transData.inverted().transform((x, y))
|
|
t = Text(
|
|
data_x, data_y,
|
|
text=self.get_text(lev, self.labelFmt),
|
|
rotation=rotation,
|
|
horizontalalignment='center', verticalalignment='center',
|
|
zorder=self._clabel_zorder,
|
|
color=self.labelMappable.to_rgba(cvalue, alpha=self.get_alpha()),
|
|
fontproperties=self._label_font_props,
|
|
clip_box=self.axes.bbox)
|
|
self.labelTexts.append(t)
|
|
self.labelCValues.append(cvalue)
|
|
self.labelXYs.append((x, y))
|
|
# Add label to plot here - useful for manual mode label selection
|
|
self.axes.add_artist(t)
|
|
|
|
def add_label_clabeltext(self, x, y, rotation, lev, cvalue):
|
|
"""Add contour label with `.Text.set_transform_rotates_text`."""
|
|
self.add_label(x, y, rotation, lev, cvalue)
|
|
# Grab the last added text, and reconfigure its rotation.
|
|
t = self.labelTexts[-1]
|
|
data_rotation, = self.axes.transData.inverted().transform_angles(
|
|
[rotation], [[x, y]])
|
|
t.set(rotation=data_rotation, transform_rotates_text=True)
|
|
|
|
def add_label_near(self, x, y, inline=True, inline_spacing=5,
|
|
transform=None):
|
|
"""
|
|
Add a label near the point ``(x, y)``.
|
|
|
|
Parameters
|
|
----------
|
|
x, y : float
|
|
The approximate location of the label.
|
|
inline : bool, default: True
|
|
If *True* remove the segment of the contour beneath the label.
|
|
inline_spacing : int, default: 5
|
|
Space in pixels to leave on each side of label when placing
|
|
inline. This spacing will be exact for labels at locations where
|
|
the contour is straight, less so for labels on curved contours.
|
|
transform : `.Transform` or `False`, default: ``self.axes.transData``
|
|
A transform applied to ``(x, y)`` before labeling. The default
|
|
causes ``(x, y)`` to be interpreted as data coordinates. `False`
|
|
is a synonym for `.IdentityTransform`; i.e. ``(x, y)`` should be
|
|
interpreted as display coordinates.
|
|
"""
|
|
|
|
if transform is None:
|
|
transform = self.axes.transData
|
|
if transform:
|
|
x, y = transform.transform((x, y))
|
|
|
|
idx_level_min, idx_vtx_min, proj = self._find_nearest_contour(
|
|
(x, y), self.labelIndiceList)
|
|
path = self._paths[idx_level_min]
|
|
level = self.labelIndiceList.index(idx_level_min)
|
|
label_width = self._get_nth_label_width(level)
|
|
rotation, path = self._split_path_and_get_label_rotation(
|
|
path, idx_vtx_min, proj, label_width, inline_spacing)
|
|
self.add_label(*proj, rotation, self.labelLevelList[idx_level_min],
|
|
self.labelCValueList[idx_level_min])
|
|
|
|
if inline:
|
|
self._paths[idx_level_min] = path
|
|
|
|
def pop_label(self, index=-1):
|
|
"""Defaults to removing last label, but any index can be supplied"""
|
|
self.labelCValues.pop(index)
|
|
t = self.labelTexts.pop(index)
|
|
t.remove()
|
|
|
|
def labels(self, inline, inline_spacing):
|
|
|
|
if self._use_clabeltext:
|
|
add_label = self.add_label_clabeltext
|
|
else:
|
|
add_label = self.add_label
|
|
|
|
for idx, (icon, lev, cvalue) in enumerate(zip(
|
|
self.labelIndiceList,
|
|
self.labelLevelList,
|
|
self.labelCValueList,
|
|
)):
|
|
trans = self.get_transform()
|
|
label_width = self._get_nth_label_width(idx)
|
|
additions = []
|
|
for subpath in self._paths[icon]._iter_connected_components():
|
|
screen_xys = trans.transform(subpath.vertices)
|
|
# Check if long enough for a label
|
|
if self.print_label(screen_xys, label_width):
|
|
x, y, idx = self.locate_label(screen_xys, label_width)
|
|
rotation, path = self._split_path_and_get_label_rotation(
|
|
subpath, idx, (x, y),
|
|
label_width, inline_spacing)
|
|
add_label(x, y, rotation, lev, cvalue) # Really add label.
|
|
if inline: # If inline, add new contours
|
|
additions.append(path)
|
|
else: # If not adding label, keep old path
|
|
additions.append(subpath)
|
|
# After looping over all segments on a contour, replace old path by new one
|
|
# if inlining.
|
|
if inline:
|
|
self._paths[icon] = Path.make_compound_path(*additions)
|
|
|
|
def remove(self):
|
|
super().remove()
|
|
for text in self.labelTexts:
|
|
text.remove()
|
|
|
|
|
|
def _is_closed_polygon(X):
|
|
"""
|
|
Return whether first and last object in a sequence are the same. These are
|
|
presumably coordinates on a polygonal curve, in which case this function
|
|
tests if that curve is closed.
|
|
"""
|
|
return np.allclose(X[0], X[-1], rtol=1e-10, atol=1e-13)
|
|
|
|
|
|
def _find_closest_point_on_path(xys, p):
|
|
"""
|
|
Parameters
|
|
----------
|
|
xys : (N, 2) array-like
|
|
Coordinates of vertices.
|
|
p : (float, float)
|
|
Coordinates of point.
|
|
|
|
Returns
|
|
-------
|
|
d2min : float
|
|
Minimum square distance of *p* to *xys*.
|
|
proj : (float, float)
|
|
Projection of *p* onto *xys*.
|
|
imin : (int, int)
|
|
Consecutive indices of vertices of segment in *xys* where *proj* is.
|
|
Segments are considered as including their end-points; i.e. if the
|
|
closest point on the path is a node in *xys* with index *i*, this
|
|
returns ``(i-1, i)``. For the special case where *xys* is a single
|
|
point, this returns ``(0, 0)``.
|
|
"""
|
|
if len(xys) == 1:
|
|
return (((p - xys[0]) ** 2).sum(), xys[0], (0, 0))
|
|
dxys = xys[1:] - xys[:-1] # Individual segment vectors.
|
|
norms = (dxys ** 2).sum(axis=1)
|
|
norms[norms == 0] = 1 # For zero-length segment, replace 0/0 by 0/1.
|
|
rel_projs = np.clip( # Project onto each segment in relative 0-1 coords.
|
|
((p - xys[:-1]) * dxys).sum(axis=1) / norms,
|
|
0, 1)[:, None]
|
|
projs = xys[:-1] + rel_projs * dxys # Projs. onto each segment, in (x, y).
|
|
d2s = ((projs - p) ** 2).sum(axis=1) # Squared distances.
|
|
imin = np.argmin(d2s)
|
|
return (d2s[imin], projs[imin], (imin, imin+1))
|
|
|
|
|
|
_docstring.interpd.update(contour_set_attributes=r"""
|
|
Attributes
|
|
----------
|
|
ax : `~matplotlib.axes.Axes`
|
|
The Axes object in which the contours are drawn.
|
|
|
|
collections : `.silent_list` of `.PathCollection`\s
|
|
The `.Artist`\s representing the contour. This is a list of
|
|
`.PathCollection`\s for both line and filled contours.
|
|
|
|
levels : array
|
|
The values of the contour levels.
|
|
|
|
layers : array
|
|
Same as levels for line contours; half-way between
|
|
levels for filled contours. See ``ContourSet._process_colors``.
|
|
""")
|
|
|
|
|
|
@_docstring.dedent_interpd
|
|
class ContourSet(ContourLabeler, mcoll.Collection):
|
|
"""
|
|
Store a set of contour lines or filled regions.
|
|
|
|
User-callable method: `~.Axes.clabel`
|
|
|
|
Parameters
|
|
----------
|
|
ax : `~matplotlib.axes.Axes`
|
|
|
|
levels : [level0, level1, ..., leveln]
|
|
A list of floating point numbers indicating the contour levels.
|
|
|
|
allsegs : [level0segs, level1segs, ...]
|
|
List of all the polygon segments for all the *levels*.
|
|
For contour lines ``len(allsegs) == len(levels)``, and for
|
|
filled contour regions ``len(allsegs) = len(levels)-1``. The lists
|
|
should look like ::
|
|
|
|
level0segs = [polygon0, polygon1, ...]
|
|
polygon0 = [[x0, y0], [x1, y1], ...]
|
|
|
|
allkinds : ``None`` or [level0kinds, level1kinds, ...]
|
|
Optional list of all the polygon vertex kinds (code types), as
|
|
described and used in Path. This is used to allow multiply-
|
|
connected paths such as holes within filled polygons.
|
|
If not ``None``, ``len(allkinds) == len(allsegs)``. The lists
|
|
should look like ::
|
|
|
|
level0kinds = [polygon0kinds, ...]
|
|
polygon0kinds = [vertexcode0, vertexcode1, ...]
|
|
|
|
If *allkinds* is not ``None``, usually all polygons for a
|
|
particular contour level are grouped together so that
|
|
``level0segs = [polygon0]`` and ``level0kinds = [polygon0kinds]``.
|
|
|
|
**kwargs
|
|
Keyword arguments are as described in the docstring of
|
|
`~.Axes.contour`.
|
|
|
|
%(contour_set_attributes)s
|
|
"""
|
|
|
|
def __init__(self, ax, *args,
|
|
levels=None, filled=False, linewidths=None, linestyles=None,
|
|
hatches=(None,), alpha=None, origin=None, extent=None,
|
|
cmap=None, colors=None, norm=None, vmin=None, vmax=None,
|
|
extend='neither', antialiased=None, nchunk=0, locator=None,
|
|
transform=None, negative_linestyles=None, clip_path=None,
|
|
**kwargs):
|
|
"""
|
|
Draw contour lines or filled regions, depending on
|
|
whether keyword arg *filled* is ``False`` (default) or ``True``.
|
|
|
|
Call signature::
|
|
|
|
ContourSet(ax, levels, allsegs, [allkinds], **kwargs)
|
|
|
|
Parameters
|
|
----------
|
|
ax : `~matplotlib.axes.Axes`
|
|
The `~.axes.Axes` object to draw on.
|
|
|
|
levels : [level0, level1, ..., leveln]
|
|
A list of floating point numbers indicating the contour
|
|
levels.
|
|
|
|
allsegs : [level0segs, level1segs, ...]
|
|
List of all the polygon segments for all the *levels*.
|
|
For contour lines ``len(allsegs) == len(levels)``, and for
|
|
filled contour regions ``len(allsegs) = len(levels)-1``. The lists
|
|
should look like ::
|
|
|
|
level0segs = [polygon0, polygon1, ...]
|
|
polygon0 = [[x0, y0], [x1, y1], ...]
|
|
|
|
allkinds : [level0kinds, level1kinds, ...], optional
|
|
Optional list of all the polygon vertex kinds (code types), as
|
|
described and used in Path. This is used to allow multiply-
|
|
connected paths such as holes within filled polygons.
|
|
If not ``None``, ``len(allkinds) == len(allsegs)``. The lists
|
|
should look like ::
|
|
|
|
level0kinds = [polygon0kinds, ...]
|
|
polygon0kinds = [vertexcode0, vertexcode1, ...]
|
|
|
|
If *allkinds* is not ``None``, usually all polygons for a
|
|
particular contour level are grouped together so that
|
|
``level0segs = [polygon0]`` and ``level0kinds = [polygon0kinds]``.
|
|
|
|
**kwargs
|
|
Keyword arguments are as described in the docstring of
|
|
`~.Axes.contour`.
|
|
"""
|
|
if antialiased is None and filled:
|
|
# Eliminate artifacts; we are not stroking the boundaries.
|
|
antialiased = False
|
|
# The default for line contours will be taken from the
|
|
# LineCollection default, which uses :rc:`lines.antialiased`.
|
|
super().__init__(
|
|
antialiaseds=antialiased,
|
|
alpha=alpha,
|
|
clip_path=clip_path,
|
|
transform=transform,
|
|
)
|
|
self.axes = ax
|
|
self.levels = levels
|
|
self.filled = filled
|
|
self.hatches = hatches
|
|
self.origin = origin
|
|
self.extent = extent
|
|
self.colors = colors
|
|
self.extend = extend
|
|
|
|
self.nchunk = nchunk
|
|
self.locator = locator
|
|
if (isinstance(norm, mcolors.LogNorm)
|
|
or isinstance(self.locator, ticker.LogLocator)):
|
|
self.logscale = True
|
|
if norm is None:
|
|
norm = mcolors.LogNorm()
|
|
else:
|
|
self.logscale = False
|
|
|
|
_api.check_in_list([None, 'lower', 'upper', 'image'], origin=origin)
|
|
if self.extent is not None and len(self.extent) != 4:
|
|
raise ValueError(
|
|
"If given, 'extent' must be None or (x0, x1, y0, y1)")
|
|
if self.colors is not None and cmap is not None:
|
|
raise ValueError('Either colors or cmap must be None')
|
|
if self.origin == 'image':
|
|
self.origin = mpl.rcParams['image.origin']
|
|
|
|
self._orig_linestyles = linestyles # Only kept for user access.
|
|
self.negative_linestyles = negative_linestyles
|
|
# If negative_linestyles was not defined as a keyword argument, define
|
|
# negative_linestyles with rcParams
|
|
if self.negative_linestyles is None:
|
|
self.negative_linestyles = \
|
|
mpl.rcParams['contour.negative_linestyle']
|
|
|
|
kwargs = self._process_args(*args, **kwargs)
|
|
self._process_levels()
|
|
|
|
self._extend_min = self.extend in ['min', 'both']
|
|
self._extend_max = self.extend in ['max', 'both']
|
|
if self.colors is not None:
|
|
ncolors = len(self.levels)
|
|
if self.filled:
|
|
ncolors -= 1
|
|
i0 = 0
|
|
|
|
# Handle the case where colors are given for the extended
|
|
# parts of the contour.
|
|
|
|
use_set_under_over = False
|
|
# if we are extending the lower end, and we've been given enough
|
|
# colors then skip the first color in the resulting cmap. For the
|
|
# extend_max case we don't need to worry about passing more colors
|
|
# than ncolors as ListedColormap will clip.
|
|
total_levels = (ncolors +
|
|
int(self._extend_min) +
|
|
int(self._extend_max))
|
|
if (len(self.colors) == total_levels and
|
|
(self._extend_min or self._extend_max)):
|
|
use_set_under_over = True
|
|
if self._extend_min:
|
|
i0 = 1
|
|
|
|
cmap = mcolors.ListedColormap(self.colors[i0:None], N=ncolors)
|
|
|
|
if use_set_under_over:
|
|
if self._extend_min:
|
|
cmap.set_under(self.colors[0])
|
|
if self._extend_max:
|
|
cmap.set_over(self.colors[-1])
|
|
|
|
# label lists must be initialized here
|
|
self.labelTexts = []
|
|
self.labelCValues = []
|
|
|
|
self.set_cmap(cmap)
|
|
if norm is not None:
|
|
self.set_norm(norm)
|
|
with self.norm.callbacks.blocked(signal="changed"):
|
|
if vmin is not None:
|
|
self.norm.vmin = vmin
|
|
if vmax is not None:
|
|
self.norm.vmax = vmax
|
|
self.norm._changed()
|
|
self._process_colors()
|
|
|
|
if self._paths is None:
|
|
self._paths = self._make_paths_from_contour_generator()
|
|
|
|
if self.filled:
|
|
if linewidths is not None:
|
|
_api.warn_external('linewidths is ignored by contourf')
|
|
# Lower and upper contour levels.
|
|
lowers, uppers = self._get_lowers_and_uppers()
|
|
self.set(
|
|
edgecolor="none",
|
|
# Default zorder taken from Collection
|
|
zorder=kwargs.pop("zorder", 1),
|
|
)
|
|
|
|
else:
|
|
self.set(
|
|
facecolor="none",
|
|
linewidths=self._process_linewidths(linewidths),
|
|
linestyle=self._process_linestyles(linestyles),
|
|
# Default zorder taken from LineCollection, which is higher
|
|
# than for filled contours so that lines are displayed on top.
|
|
zorder=kwargs.pop("zorder", 2),
|
|
label="_nolegend_",
|
|
)
|
|
|
|
self.axes.add_collection(self, autolim=False)
|
|
self.sticky_edges.x[:] = [self._mins[0], self._maxs[0]]
|
|
self.sticky_edges.y[:] = [self._mins[1], self._maxs[1]]
|
|
self.axes.update_datalim([self._mins, self._maxs])
|
|
self.axes.autoscale_view(tight=True)
|
|
|
|
self.changed() # set the colors
|
|
|
|
if kwargs:
|
|
_api.warn_external(
|
|
'The following kwargs were not used by contour: ' +
|
|
", ".join(map(repr, kwargs))
|
|
)
|
|
|
|
allsegs = property(lambda self: [
|
|
[subp.vertices for subp in p._iter_connected_components()]
|
|
for p in self.get_paths()])
|
|
allkinds = property(lambda self: [
|
|
[subp.codes for subp in p._iter_connected_components()]
|
|
for p in self.get_paths()])
|
|
tcolors = _api.deprecated("3.8")(property(lambda self: [
|
|
(tuple(rgba),) for rgba in self.to_rgba(self.cvalues, self.alpha)]))
|
|
tlinewidths = _api.deprecated("3.8")(property(lambda self: [
|
|
(w,) for w in self.get_linewidths()]))
|
|
alpha = property(lambda self: self.get_alpha())
|
|
linestyles = property(lambda self: self._orig_linestyles)
|
|
|
|
@_api.deprecated("3.8", alternative="set_antialiased or get_antialiased",
|
|
addendum="Note that get_antialiased returns an array.")
|
|
@property
|
|
def antialiased(self):
|
|
return all(self.get_antialiased())
|
|
|
|
@antialiased.setter
|
|
def antialiased(self, aa):
|
|
self.set_antialiased(aa)
|
|
|
|
@_api.deprecated("3.8")
|
|
@property
|
|
def collections(self):
|
|
# On access, make oneself invisible and instead add the old-style collections
|
|
# (one PathCollection per level). We do not try to further split contours into
|
|
# connected components as we already lost track of what pairs of contours need
|
|
# to be considered as single units to draw filled regions with holes.
|
|
if not hasattr(self, "_old_style_split_collections"):
|
|
self.set_visible(False)
|
|
fcs = self.get_facecolor()
|
|
ecs = self.get_edgecolor()
|
|
lws = self.get_linewidth()
|
|
lss = self.get_linestyle()
|
|
self._old_style_split_collections = []
|
|
for idx, path in enumerate(self._paths):
|
|
pc = mcoll.PathCollection(
|
|
[path] if len(path.vertices) else [],
|
|
alpha=self.get_alpha(),
|
|
antialiaseds=self._antialiaseds[idx % len(self._antialiaseds)],
|
|
transform=self.get_transform(),
|
|
zorder=self.get_zorder(),
|
|
label="_nolegend_",
|
|
facecolor=fcs[idx] if len(fcs) else "none",
|
|
edgecolor=ecs[idx] if len(ecs) else "none",
|
|
linewidths=[lws[idx % len(lws)]],
|
|
linestyles=[lss[idx % len(lss)]],
|
|
)
|
|
if self.filled:
|
|
pc.set(hatch=self.hatches[idx % len(self.hatches)])
|
|
self._old_style_split_collections.append(pc)
|
|
for col in self._old_style_split_collections:
|
|
self.axes.add_collection(col)
|
|
return self._old_style_split_collections
|
|
|
|
def get_transform(self):
|
|
"""Return the `.Transform` instance used by this ContourSet."""
|
|
if self._transform is None:
|
|
self._transform = self.axes.transData
|
|
elif (not isinstance(self._transform, mtransforms.Transform)
|
|
and hasattr(self._transform, '_as_mpl_transform')):
|
|
self._transform = self._transform._as_mpl_transform(self.axes)
|
|
return self._transform
|
|
|
|
def __getstate__(self):
|
|
state = self.__dict__.copy()
|
|
# the C object _contour_generator cannot currently be pickled. This
|
|
# isn't a big issue as it is not actually used once the contour has
|
|
# been calculated.
|
|
state['_contour_generator'] = None
|
|
return state
|
|
|
|
def legend_elements(self, variable_name='x', str_format=str):
|
|
"""
|
|
Return a list of artists and labels suitable for passing through
|
|
to `~.Axes.legend` which represent this ContourSet.
|
|
|
|
The labels have the form "0 < x <= 1" stating the data ranges which
|
|
the artists represent.
|
|
|
|
Parameters
|
|
----------
|
|
variable_name : str
|
|
The string used inside the inequality used on the labels.
|
|
str_format : function: float -> str
|
|
Function used to format the numbers in the labels.
|
|
|
|
Returns
|
|
-------
|
|
artists : list[`.Artist`]
|
|
A list of the artists.
|
|
labels : list[str]
|
|
A list of the labels.
|
|
"""
|
|
artists = []
|
|
labels = []
|
|
|
|
if self.filled:
|
|
lowers, uppers = self._get_lowers_and_uppers()
|
|
n_levels = len(self._paths)
|
|
for idx in range(n_levels):
|
|
artists.append(mpatches.Rectangle(
|
|
(0, 0), 1, 1,
|
|
facecolor=self.get_facecolor()[idx],
|
|
hatch=self.hatches[idx % len(self.hatches)],
|
|
))
|
|
lower = str_format(lowers[idx])
|
|
upper = str_format(uppers[idx])
|
|
if idx == 0 and self.extend in ('min', 'both'):
|
|
labels.append(fr'${variable_name} \leq {lower}s$')
|
|
elif idx == n_levels - 1 and self.extend in ('max', 'both'):
|
|
labels.append(fr'${variable_name} > {upper}s$')
|
|
else:
|
|
labels.append(fr'${lower} < {variable_name} \leq {upper}$')
|
|
else:
|
|
for idx, level in enumerate(self.levels):
|
|
artists.append(Line2D(
|
|
[], [],
|
|
color=self.get_edgecolor()[idx],
|
|
linewidth=self.get_linewidths()[idx],
|
|
linestyle=self.get_linestyles()[idx],
|
|
))
|
|
labels.append(fr'${variable_name} = {str_format(level)}$')
|
|
|
|
return artists, labels
|
|
|
|
def _process_args(self, *args, **kwargs):
|
|
"""
|
|
Process *args* and *kwargs*; override in derived classes.
|
|
|
|
Must set self.levels, self.zmin and self.zmax, and update axes limits.
|
|
"""
|
|
self.levels = args[0]
|
|
allsegs = args[1]
|
|
allkinds = args[2] if len(args) > 2 else None
|
|
self.zmax = np.max(self.levels)
|
|
self.zmin = np.min(self.levels)
|
|
|
|
if allkinds is None:
|
|
allkinds = [[None] * len(segs) for segs in allsegs]
|
|
|
|
# Check lengths of levels and allsegs.
|
|
if self.filled:
|
|
if len(allsegs) != len(self.levels) - 1:
|
|
raise ValueError('must be one less number of segments as '
|
|
'levels')
|
|
else:
|
|
if len(allsegs) != len(self.levels):
|
|
raise ValueError('must be same number of segments as levels')
|
|
|
|
# Check length of allkinds.
|
|
if len(allkinds) != len(allsegs):
|
|
raise ValueError('allkinds has different length to allsegs')
|
|
|
|
# Determine x, y bounds and update axes data limits.
|
|
flatseglist = [s for seg in allsegs for s in seg]
|
|
points = np.concatenate(flatseglist, axis=0)
|
|
self._mins = points.min(axis=0)
|
|
self._maxs = points.max(axis=0)
|
|
|
|
# Each entry in (allsegs, allkinds) is a list of (segs, kinds): segs is a list
|
|
# of (N, 2) arrays of xy coordinates, kinds is a list of arrays of corresponding
|
|
# pathcodes. However, kinds can also be None; in which case all paths in that
|
|
# list are codeless (this case is normalized above). These lists are used to
|
|
# construct paths, which then get concatenated.
|
|
self._paths = [Path.make_compound_path(*map(Path, segs, kinds))
|
|
for segs, kinds in zip(allsegs, allkinds)]
|
|
|
|
return kwargs
|
|
|
|
def _make_paths_from_contour_generator(self):
|
|
"""Compute ``paths`` using C extension."""
|
|
if self._paths is not None:
|
|
return self._paths
|
|
paths = []
|
|
empty_path = Path(np.empty((0, 2)))
|
|
if self.filled:
|
|
lowers, uppers = self._get_lowers_and_uppers()
|
|
for level, level_upper in zip(lowers, uppers):
|
|
vertices, kinds = \
|
|
self._contour_generator.create_filled_contour(
|
|
level, level_upper)
|
|
paths.append(Path(np.concatenate(vertices), np.concatenate(kinds))
|
|
if len(vertices) else empty_path)
|
|
else:
|
|
for level in self.levels:
|
|
vertices, kinds = self._contour_generator.create_contour(level)
|
|
paths.append(Path(np.concatenate(vertices), np.concatenate(kinds))
|
|
if len(vertices) else empty_path)
|
|
return paths
|
|
|
|
def _get_lowers_and_uppers(self):
|
|
"""
|
|
Return ``(lowers, uppers)`` for filled contours.
|
|
"""
|
|
lowers = self._levels[:-1]
|
|
if self.zmin == lowers[0]:
|
|
# Include minimum values in lowest interval
|
|
lowers = lowers.copy() # so we don't change self._levels
|
|
if self.logscale:
|
|
lowers[0] = 0.99 * self.zmin
|
|
else:
|
|
lowers[0] -= 1
|
|
uppers = self._levels[1:]
|
|
return (lowers, uppers)
|
|
|
|
def changed(self):
|
|
if not hasattr(self, "cvalues"):
|
|
self._process_colors() # Sets cvalues.
|
|
# Force an autoscale immediately because self.to_rgba() calls
|
|
# autoscale_None() internally with the data passed to it,
|
|
# so if vmin/vmax are not set yet, this would override them with
|
|
# content from *cvalues* rather than levels like we want
|
|
self.norm.autoscale_None(self.levels)
|
|
self.set_array(self.cvalues)
|
|
self.update_scalarmappable()
|
|
alphas = np.broadcast_to(self.get_alpha(), len(self.cvalues))
|
|
for label, cv, alpha in zip(self.labelTexts, self.labelCValues, alphas):
|
|
label.set_alpha(alpha)
|
|
label.set_color(self.labelMappable.to_rgba(cv))
|
|
super().changed()
|
|
|
|
def _autolev(self, N):
|
|
"""
|
|
Select contour levels to span the data.
|
|
|
|
The target number of levels, *N*, is used only when the
|
|
scale is not log and default locator is used.
|
|
|
|
We need two more levels for filled contours than for
|
|
line contours, because for the latter we need to specify
|
|
the lower and upper boundary of each range. For example,
|
|
a single contour boundary, say at z = 0, requires only
|
|
one contour line, but two filled regions, and therefore
|
|
three levels to provide boundaries for both regions.
|
|
"""
|
|
if self.locator is None:
|
|
if self.logscale:
|
|
self.locator = ticker.LogLocator()
|
|
else:
|
|
self.locator = ticker.MaxNLocator(N + 1, min_n_ticks=1)
|
|
|
|
lev = self.locator.tick_values(self.zmin, self.zmax)
|
|
|
|
try:
|
|
if self.locator._symmetric:
|
|
return lev
|
|
except AttributeError:
|
|
pass
|
|
|
|
# Trim excess levels the locator may have supplied.
|
|
under = np.nonzero(lev < self.zmin)[0]
|
|
i0 = under[-1] if len(under) else 0
|
|
over = np.nonzero(lev > self.zmax)[0]
|
|
i1 = over[0] + 1 if len(over) else len(lev)
|
|
if self.extend in ('min', 'both'):
|
|
i0 += 1
|
|
if self.extend in ('max', 'both'):
|
|
i1 -= 1
|
|
|
|
if i1 - i0 < 3:
|
|
i0, i1 = 0, len(lev)
|
|
|
|
return lev[i0:i1]
|
|
|
|
def _process_contour_level_args(self, args, z_dtype):
|
|
"""
|
|
Determine the contour levels and store in self.levels.
|
|
"""
|
|
if self.levels is None:
|
|
if args:
|
|
levels_arg = args[0]
|
|
elif np.issubdtype(z_dtype, bool):
|
|
if self.filled:
|
|
levels_arg = [0, .5, 1]
|
|
else:
|
|
levels_arg = [.5]
|
|
else:
|
|
levels_arg = 7 # Default, hard-wired.
|
|
else:
|
|
levels_arg = self.levels
|
|
if isinstance(levels_arg, Integral):
|
|
self.levels = self._autolev(levels_arg)
|
|
else:
|
|
self.levels = np.asarray(levels_arg, np.float64)
|
|
if self.filled and len(self.levels) < 2:
|
|
raise ValueError("Filled contours require at least 2 levels.")
|
|
if len(self.levels) > 1 and np.min(np.diff(self.levels)) <= 0.0:
|
|
raise ValueError("Contour levels must be increasing")
|
|
|
|
def _process_levels(self):
|
|
"""
|
|
Assign values to :attr:`layers` based on :attr:`levels`,
|
|
adding extended layers as needed if contours are filled.
|
|
|
|
For line contours, layers simply coincide with levels;
|
|
a line is a thin layer. No extended levels are needed
|
|
with line contours.
|
|
"""
|
|
# Make a private _levels to include extended regions; we
|
|
# want to leave the original levels attribute unchanged.
|
|
# (Colorbar needs this even for line contours.)
|
|
self._levels = list(self.levels)
|
|
|
|
if self.logscale:
|
|
lower, upper = 1e-250, 1e250
|
|
else:
|
|
lower, upper = -1e250, 1e250
|
|
|
|
if self.extend in ('both', 'min'):
|
|
self._levels.insert(0, lower)
|
|
if self.extend in ('both', 'max'):
|
|
self._levels.append(upper)
|
|
self._levels = np.asarray(self._levels)
|
|
|
|
if not self.filled:
|
|
self.layers = self.levels
|
|
return
|
|
|
|
# Layer values are mid-way between levels in screen space.
|
|
if self.logscale:
|
|
# Avoid overflow by taking sqrt before multiplying.
|
|
self.layers = (np.sqrt(self._levels[:-1])
|
|
* np.sqrt(self._levels[1:]))
|
|
else:
|
|
self.layers = 0.5 * (self._levels[:-1] + self._levels[1:])
|
|
|
|
def _process_colors(self):
|
|
"""
|
|
Color argument processing for contouring.
|
|
|
|
Note that we base the colormapping on the contour levels
|
|
and layers, not on the actual range of the Z values. This
|
|
means we don't have to worry about bad values in Z, and we
|
|
always have the full dynamic range available for the selected
|
|
levels.
|
|
|
|
The color is based on the midpoint of the layer, except for
|
|
extended end layers. By default, the norm vmin and vmax
|
|
are the extreme values of the non-extended levels. Hence,
|
|
the layer color extremes are not the extreme values of
|
|
the colormap itself, but approach those values as the number
|
|
of levels increases. An advantage of this scheme is that
|
|
line contours, when added to filled contours, take on
|
|
colors that are consistent with those of the filled regions;
|
|
for example, a contour line on the boundary between two
|
|
regions will have a color intermediate between those
|
|
of the regions.
|
|
|
|
"""
|
|
self.monochrome = self.cmap.monochrome
|
|
if self.colors is not None:
|
|
# Generate integers for direct indexing.
|
|
i0, i1 = 0, len(self.levels)
|
|
if self.filled:
|
|
i1 -= 1
|
|
# Out of range indices for over and under:
|
|
if self.extend in ('both', 'min'):
|
|
i0 -= 1
|
|
if self.extend in ('both', 'max'):
|
|
i1 += 1
|
|
self.cvalues = list(range(i0, i1))
|
|
self.set_norm(mcolors.NoNorm())
|
|
else:
|
|
self.cvalues = self.layers
|
|
self.norm.autoscale_None(self.levels)
|
|
self.set_array(self.cvalues)
|
|
self.update_scalarmappable()
|
|
if self.extend in ('both', 'max', 'min'):
|
|
self.norm.clip = False
|
|
|
|
def _process_linewidths(self, linewidths):
|
|
Nlev = len(self.levels)
|
|
if linewidths is None:
|
|
default_linewidth = mpl.rcParams['contour.linewidth']
|
|
if default_linewidth is None:
|
|
default_linewidth = mpl.rcParams['lines.linewidth']
|
|
return [default_linewidth] * Nlev
|
|
elif not np.iterable(linewidths):
|
|
return [linewidths] * Nlev
|
|
else:
|
|
linewidths = list(linewidths)
|
|
return (linewidths * math.ceil(Nlev / len(linewidths)))[:Nlev]
|
|
|
|
def _process_linestyles(self, linestyles):
|
|
Nlev = len(self.levels)
|
|
if linestyles is None:
|
|
tlinestyles = ['solid'] * Nlev
|
|
if self.monochrome:
|
|
eps = - (self.zmax - self.zmin) * 1e-15
|
|
for i, lev in enumerate(self.levels):
|
|
if lev < eps:
|
|
tlinestyles[i] = self.negative_linestyles
|
|
else:
|
|
if isinstance(linestyles, str):
|
|
tlinestyles = [linestyles] * Nlev
|
|
elif np.iterable(linestyles):
|
|
tlinestyles = list(linestyles)
|
|
if len(tlinestyles) < Nlev:
|
|
nreps = int(np.ceil(Nlev / len(linestyles)))
|
|
tlinestyles = tlinestyles * nreps
|
|
if len(tlinestyles) > Nlev:
|
|
tlinestyles = tlinestyles[:Nlev]
|
|
else:
|
|
raise ValueError("Unrecognized type for linestyles kwarg")
|
|
return tlinestyles
|
|
|
|
def _find_nearest_contour(self, xy, indices=None):
|
|
"""
|
|
Find the point in the unfilled contour plot that is closest (in screen
|
|
space) to point *xy*.
|
|
|
|
Parameters
|
|
----------
|
|
xy : tuple[float, float]
|
|
The reference point (in screen space).
|
|
indices : list of int or None, default: None
|
|
Indices of contour levels to consider. If None (the default), all levels
|
|
are considered.
|
|
|
|
Returns
|
|
-------
|
|
idx_level_min : int
|
|
The index of the contour level closest to *xy*.
|
|
idx_vtx_min : int
|
|
The index of the `.Path` segment closest to *xy* (at that level).
|
|
proj : (float, float)
|
|
The point in the contour plot closest to *xy*.
|
|
"""
|
|
|
|
# Convert each contour segment to pixel coordinates and then compare the given
|
|
# point to those coordinates for each contour. This is fast enough in normal
|
|
# cases, but speedups may be possible.
|
|
|
|
if self.filled:
|
|
raise ValueError("Method does not support filled contours")
|
|
|
|
if indices is None:
|
|
indices = range(len(self._paths))
|
|
|
|
d2min = np.inf
|
|
idx_level_min = idx_vtx_min = proj_min = None
|
|
|
|
for idx_level in indices:
|
|
path = self._paths[idx_level]
|
|
idx_vtx_start = 0
|
|
for subpath in path._iter_connected_components():
|
|
if not len(subpath.vertices):
|
|
continue
|
|
lc = self.get_transform().transform(subpath.vertices)
|
|
d2, proj, leg = _find_closest_point_on_path(lc, xy)
|
|
if d2 < d2min:
|
|
d2min = d2
|
|
idx_level_min = idx_level
|
|
idx_vtx_min = leg[1] + idx_vtx_start
|
|
proj_min = proj
|
|
idx_vtx_start += len(subpath)
|
|
|
|
return idx_level_min, idx_vtx_min, proj_min
|
|
|
|
def find_nearest_contour(self, x, y, indices=None, pixel=True):
|
|
"""
|
|
Find the point in the contour plot that is closest to ``(x, y)``.
|
|
|
|
This method does not support filled contours.
|
|
|
|
Parameters
|
|
----------
|
|
x, y : float
|
|
The reference point.
|
|
indices : list of int or None, default: None
|
|
Indices of contour levels to consider. If None (the default), all
|
|
levels are considered.
|
|
pixel : bool, default: True
|
|
If *True*, measure distance in pixel (screen) space, which is
|
|
useful for manual contour labeling; else, measure distance in axes
|
|
space.
|
|
|
|
Returns
|
|
-------
|
|
path : int
|
|
The index of the path that is closest to ``(x, y)``. Each path corresponds
|
|
to one contour level.
|
|
subpath : int
|
|
The index within that closest path of the subpath that is closest to
|
|
``(x, y)``. Each subpath corresponds to one unbroken contour line.
|
|
index : int
|
|
The index of the vertices within that subpath that are closest to
|
|
``(x, y)``.
|
|
xmin, ymin : float
|
|
The point in the contour plot that is closest to ``(x, y)``.
|
|
d2 : float
|
|
The squared distance from ``(xmin, ymin)`` to ``(x, y)``.
|
|
"""
|
|
segment = index = d2 = None
|
|
|
|
with ExitStack() as stack:
|
|
if not pixel:
|
|
# _find_nearest_contour works in pixel space. We want axes space, so
|
|
# effectively disable the transformation here by setting to identity.
|
|
stack.enter_context(self._cm_set(
|
|
transform=mtransforms.IdentityTransform()))
|
|
|
|
i_level, i_vtx, (xmin, ymin) = self._find_nearest_contour((x, y), indices)
|
|
|
|
if i_level is not None:
|
|
cc_cumlens = np.cumsum(
|
|
[*map(len, self._paths[i_level]._iter_connected_components())])
|
|
segment = cc_cumlens.searchsorted(i_vtx, "right")
|
|
index = i_vtx if segment == 0 else i_vtx - cc_cumlens[segment - 1]
|
|
d2 = (xmin-x)**2 + (ymin-y)**2
|
|
|
|
return (i_level, segment, index, xmin, ymin, d2)
|
|
|
|
def draw(self, renderer):
|
|
paths = self._paths
|
|
n_paths = len(paths)
|
|
if not self.filled or all(hatch is None for hatch in self.hatches):
|
|
super().draw(renderer)
|
|
return
|
|
# In presence of hatching, draw contours one at a time.
|
|
for idx in range(n_paths):
|
|
with cbook._setattr_cm(self, _paths=[paths[idx]]), self._cm_set(
|
|
hatch=self.hatches[idx % len(self.hatches)],
|
|
array=[self.get_array()[idx]],
|
|
linewidths=[self.get_linewidths()[idx % len(self.get_linewidths())]],
|
|
linestyles=[self.get_linestyles()[idx % len(self.get_linestyles())]],
|
|
):
|
|
super().draw(renderer)
|
|
|
|
|
|
@_docstring.dedent_interpd
|
|
class QuadContourSet(ContourSet):
|
|
"""
|
|
Create and store a set of contour lines or filled regions.
|
|
|
|
This class is typically not instantiated directly by the user but by
|
|
`~.Axes.contour` and `~.Axes.contourf`.
|
|
|
|
%(contour_set_attributes)s
|
|
"""
|
|
|
|
def _process_args(self, *args, corner_mask=None, algorithm=None, **kwargs):
|
|
"""
|
|
Process args and kwargs.
|
|
"""
|
|
if args and isinstance(args[0], QuadContourSet):
|
|
if self.levels is None:
|
|
self.levels = args[0].levels
|
|
self.zmin = args[0].zmin
|
|
self.zmax = args[0].zmax
|
|
self._corner_mask = args[0]._corner_mask
|
|
contour_generator = args[0]._contour_generator
|
|
self._mins = args[0]._mins
|
|
self._maxs = args[0]._maxs
|
|
self._algorithm = args[0]._algorithm
|
|
else:
|
|
import contourpy
|
|
|
|
if algorithm is None:
|
|
algorithm = mpl.rcParams['contour.algorithm']
|
|
mpl.rcParams.validate["contour.algorithm"](algorithm)
|
|
self._algorithm = algorithm
|
|
|
|
if corner_mask is None:
|
|
if self._algorithm == "mpl2005":
|
|
# mpl2005 does not support corner_mask=True so if not
|
|
# specifically requested then disable it.
|
|
corner_mask = False
|
|
else:
|
|
corner_mask = mpl.rcParams['contour.corner_mask']
|
|
self._corner_mask = corner_mask
|
|
|
|
x, y, z = self._contour_args(args, kwargs)
|
|
|
|
contour_generator = contourpy.contour_generator(
|
|
x, y, z, name=self._algorithm, corner_mask=self._corner_mask,
|
|
line_type=contourpy.LineType.SeparateCode,
|
|
fill_type=contourpy.FillType.OuterCode,
|
|
chunk_size=self.nchunk)
|
|
|
|
t = self.get_transform()
|
|
|
|
# if the transform is not trans data, and some part of it
|
|
# contains transData, transform the xs and ys to data coordinates
|
|
if (t != self.axes.transData and
|
|
any(t.contains_branch_seperately(self.axes.transData))):
|
|
trans_to_data = t - self.axes.transData
|
|
pts = np.vstack([x.flat, y.flat]).T
|
|
transformed_pts = trans_to_data.transform(pts)
|
|
x = transformed_pts[..., 0]
|
|
y = transformed_pts[..., 1]
|
|
|
|
self._mins = [ma.min(x), ma.min(y)]
|
|
self._maxs = [ma.max(x), ma.max(y)]
|
|
|
|
self._contour_generator = contour_generator
|
|
|
|
return kwargs
|
|
|
|
def _contour_args(self, args, kwargs):
|
|
if self.filled:
|
|
fn = 'contourf'
|
|
else:
|
|
fn = 'contour'
|
|
nargs = len(args)
|
|
|
|
if 0 < nargs <= 2:
|
|
z, *args = args
|
|
z = ma.asarray(z)
|
|
x, y = self._initialize_x_y(z)
|
|
elif 2 < nargs <= 4:
|
|
x, y, z_orig, *args = args
|
|
x, y, z = self._check_xyz(x, y, z_orig, kwargs)
|
|
|
|
else:
|
|
raise _api.nargs_error(fn, takes="from 1 to 4", given=nargs)
|
|
z = ma.masked_invalid(z, copy=False)
|
|
self.zmax = z.max().astype(float)
|
|
self.zmin = z.min().astype(float)
|
|
if self.logscale and self.zmin <= 0:
|
|
z = ma.masked_where(z <= 0, z)
|
|
_api.warn_external('Log scale: values of z <= 0 have been masked')
|
|
self.zmin = z.min().astype(float)
|
|
self._process_contour_level_args(args, z.dtype)
|
|
return (x, y, z)
|
|
|
|
def _check_xyz(self, x, y, z, kwargs):
|
|
"""
|
|
Check that the shapes of the input arrays match; if x and y are 1D,
|
|
convert them to 2D using meshgrid.
|
|
"""
|
|
x, y = self.axes._process_unit_info([("x", x), ("y", y)], kwargs)
|
|
|
|
x = np.asarray(x, dtype=np.float64)
|
|
y = np.asarray(y, dtype=np.float64)
|
|
z = ma.asarray(z)
|
|
|
|
if z.ndim != 2:
|
|
raise TypeError(f"Input z must be 2D, not {z.ndim}D")
|
|
if z.shape[0] < 2 or z.shape[1] < 2:
|
|
raise TypeError(f"Input z must be at least a (2, 2) shaped array, "
|
|
f"but has shape {z.shape}")
|
|
Ny, Nx = z.shape
|
|
|
|
if x.ndim != y.ndim:
|
|
raise TypeError(f"Number of dimensions of x ({x.ndim}) and y "
|
|
f"({y.ndim}) do not match")
|
|
if x.ndim == 1:
|
|
nx, = x.shape
|
|
ny, = y.shape
|
|
if nx != Nx:
|
|
raise TypeError(f"Length of x ({nx}) must match number of "
|
|
f"columns in z ({Nx})")
|
|
if ny != Ny:
|
|
raise TypeError(f"Length of y ({ny}) must match number of "
|
|
f"rows in z ({Ny})")
|
|
x, y = np.meshgrid(x, y)
|
|
elif x.ndim == 2:
|
|
if x.shape != z.shape:
|
|
raise TypeError(
|
|
f"Shapes of x {x.shape} and z {z.shape} do not match")
|
|
if y.shape != z.shape:
|
|
raise TypeError(
|
|
f"Shapes of y {y.shape} and z {z.shape} do not match")
|
|
else:
|
|
raise TypeError(f"Inputs x and y must be 1D or 2D, not {x.ndim}D")
|
|
|
|
return x, y, z
|
|
|
|
def _initialize_x_y(self, z):
|
|
"""
|
|
Return X, Y arrays such that contour(Z) will match imshow(Z)
|
|
if origin is not None.
|
|
The center of pixel Z[i, j] depends on origin:
|
|
if origin is None, x = j, y = i;
|
|
if origin is 'lower', x = j + 0.5, y = i + 0.5;
|
|
if origin is 'upper', x = j + 0.5, y = Nrows - i - 0.5
|
|
If extent is not None, x and y will be scaled to match,
|
|
as in imshow.
|
|
If origin is None and extent is not None, then extent
|
|
will give the minimum and maximum values of x and y.
|
|
"""
|
|
if z.ndim != 2:
|
|
raise TypeError(f"Input z must be 2D, not {z.ndim}D")
|
|
elif z.shape[0] < 2 or z.shape[1] < 2:
|
|
raise TypeError(f"Input z must be at least a (2, 2) shaped array, "
|
|
f"but has shape {z.shape}")
|
|
else:
|
|
Ny, Nx = z.shape
|
|
if self.origin is None: # Not for image-matching.
|
|
if self.extent is None:
|
|
return np.meshgrid(np.arange(Nx), np.arange(Ny))
|
|
else:
|
|
x0, x1, y0, y1 = self.extent
|
|
x = np.linspace(x0, x1, Nx)
|
|
y = np.linspace(y0, y1, Ny)
|
|
return np.meshgrid(x, y)
|
|
# Match image behavior:
|
|
if self.extent is None:
|
|
x0, x1, y0, y1 = (0, Nx, 0, Ny)
|
|
else:
|
|
x0, x1, y0, y1 = self.extent
|
|
dx = (x1 - x0) / Nx
|
|
dy = (y1 - y0) / Ny
|
|
x = x0 + (np.arange(Nx) + 0.5) * dx
|
|
y = y0 + (np.arange(Ny) + 0.5) * dy
|
|
if self.origin == 'upper':
|
|
y = y[::-1]
|
|
return np.meshgrid(x, y)
|
|
|
|
|
|
_docstring.interpd.update(contour_doc="""
|
|
`.contour` and `.contourf` draw contour lines and filled contours,
|
|
respectively. Except as noted, function signatures and return values
|
|
are the same for both versions.
|
|
|
|
Parameters
|
|
----------
|
|
X, Y : array-like, optional
|
|
The coordinates of the values in *Z*.
|
|
|
|
*X* and *Y* must both be 2D with the same shape as *Z* (e.g.
|
|
created via `numpy.meshgrid`), or they must both be 1-D such
|
|
that ``len(X) == N`` is the number of columns in *Z* and
|
|
``len(Y) == M`` is the number of rows in *Z*.
|
|
|
|
*X* and *Y* must both be ordered monotonically.
|
|
|
|
If not given, they are assumed to be integer indices, i.e.
|
|
``X = range(N)``, ``Y = range(M)``.
|
|
|
|
Z : (M, N) array-like
|
|
The height values over which the contour is drawn. Color-mapping is
|
|
controlled by *cmap*, *norm*, *vmin*, and *vmax*.
|
|
|
|
levels : int or array-like, optional
|
|
Determines the number and positions of the contour lines / regions.
|
|
|
|
If an int *n*, use `~matplotlib.ticker.MaxNLocator`, which tries
|
|
to automatically choose no more than *n+1* "nice" contour levels
|
|
between minimum and maximum numeric values of *Z*.
|
|
|
|
If array-like, draw contour lines at the specified levels.
|
|
The values must be in increasing order.
|
|
|
|
Returns
|
|
-------
|
|
`~.contour.QuadContourSet`
|
|
|
|
Other Parameters
|
|
----------------
|
|
corner_mask : bool, default: :rc:`contour.corner_mask`
|
|
Enable/disable corner masking, which only has an effect if *Z* is
|
|
a masked array. If ``False``, any quad touching a masked point is
|
|
masked out. If ``True``, only the triangular corners of quads
|
|
nearest those points are always masked out, other triangular
|
|
corners comprising three unmasked points are contoured as usual.
|
|
|
|
colors : color string or sequence of colors, optional
|
|
The colors of the levels, i.e. the lines for `.contour` and the
|
|
areas for `.contourf`.
|
|
|
|
The sequence is cycled for the levels in ascending order. If the
|
|
sequence is shorter than the number of levels, it's repeated.
|
|
|
|
As a shortcut, single color strings may be used in place of
|
|
one-element lists, i.e. ``'red'`` instead of ``['red']`` to color
|
|
all levels with the same color. This shortcut does only work for
|
|
color strings, not for other ways of specifying colors.
|
|
|
|
By default (value *None*), the colormap specified by *cmap*
|
|
will be used.
|
|
|
|
alpha : float, default: 1
|
|
The alpha blending value, between 0 (transparent) and 1 (opaque).
|
|
|
|
%(cmap_doc)s
|
|
|
|
This parameter is ignored if *colors* is set.
|
|
|
|
%(norm_doc)s
|
|
|
|
This parameter is ignored if *colors* is set.
|
|
|
|
%(vmin_vmax_doc)s
|
|
|
|
If *vmin* or *vmax* are not given, the default color scaling is based on
|
|
*levels*.
|
|
|
|
This parameter is ignored if *colors* is set.
|
|
|
|
origin : {*None*, 'upper', 'lower', 'image'}, default: None
|
|
Determines the orientation and exact position of *Z* by specifying
|
|
the position of ``Z[0, 0]``. This is only relevant, if *X*, *Y*
|
|
are not given.
|
|
|
|
- *None*: ``Z[0, 0]`` is at X=0, Y=0 in the lower left corner.
|
|
- 'lower': ``Z[0, 0]`` is at X=0.5, Y=0.5 in the lower left corner.
|
|
- 'upper': ``Z[0, 0]`` is at X=N+0.5, Y=0.5 in the upper left
|
|
corner.
|
|
- 'image': Use the value from :rc:`image.origin`.
|
|
|
|
extent : (x0, x1, y0, y1), optional
|
|
If *origin* is not *None*, then *extent* is interpreted as in
|
|
`.imshow`: it gives the outer pixel boundaries. In this case, the
|
|
position of Z[0, 0] is the center of the pixel, not a corner. If
|
|
*origin* is *None*, then (*x0*, *y0*) is the position of Z[0, 0],
|
|
and (*x1*, *y1*) is the position of Z[-1, -1].
|
|
|
|
This argument is ignored if *X* and *Y* are specified in the call
|
|
to contour.
|
|
|
|
locator : ticker.Locator subclass, optional
|
|
The locator is used to determine the contour levels if they
|
|
are not given explicitly via *levels*.
|
|
Defaults to `~.ticker.MaxNLocator`.
|
|
|
|
extend : {'neither', 'both', 'min', 'max'}, default: 'neither'
|
|
Determines the ``contourf``-coloring of values that are outside the
|
|
*levels* range.
|
|
|
|
If 'neither', values outside the *levels* range are not colored.
|
|
If 'min', 'max' or 'both', color the values below, above or below
|
|
and above the *levels* range.
|
|
|
|
Values below ``min(levels)`` and above ``max(levels)`` are mapped
|
|
to the under/over values of the `.Colormap`. Note that most
|
|
colormaps do not have dedicated colors for these by default, so
|
|
that the over and under values are the edge values of the colormap.
|
|
You may want to set these values explicitly using
|
|
`.Colormap.set_under` and `.Colormap.set_over`.
|
|
|
|
.. note::
|
|
|
|
An existing `.QuadContourSet` does not get notified if
|
|
properties of its colormap are changed. Therefore, an explicit
|
|
call `.QuadContourSet.changed()` is needed after modifying the
|
|
colormap. The explicit call can be left out, if a colorbar is
|
|
assigned to the `.QuadContourSet` because it internally calls
|
|
`.QuadContourSet.changed()`.
|
|
|
|
Example::
|
|
|
|
x = np.arange(1, 10)
|
|
y = x.reshape(-1, 1)
|
|
h = x * y
|
|
|
|
cs = plt.contourf(h, levels=[10, 30, 50],
|
|
colors=['#808080', '#A0A0A0', '#C0C0C0'], extend='both')
|
|
cs.cmap.set_over('red')
|
|
cs.cmap.set_under('blue')
|
|
cs.changed()
|
|
|
|
xunits, yunits : registered units, optional
|
|
Override axis units by specifying an instance of a
|
|
:class:`matplotlib.units.ConversionInterface`.
|
|
|
|
antialiased : bool, optional
|
|
Enable antialiasing, overriding the defaults. For
|
|
filled contours, the default is *False*. For line contours,
|
|
it is taken from :rc:`lines.antialiased`.
|
|
|
|
nchunk : int >= 0, optional
|
|
If 0, no subdivision of the domain. Specify a positive integer to
|
|
divide the domain into subdomains of *nchunk* by *nchunk* quads.
|
|
Chunking reduces the maximum length of polygons generated by the
|
|
contouring algorithm which reduces the rendering workload passed
|
|
on to the backend and also requires slightly less RAM. It can
|
|
however introduce rendering artifacts at chunk boundaries depending
|
|
on the backend, the *antialiased* flag and value of *alpha*.
|
|
|
|
linewidths : float or array-like, default: :rc:`contour.linewidth`
|
|
*Only applies to* `.contour`.
|
|
|
|
The line width of the contour lines.
|
|
|
|
If a number, all levels will be plotted with this linewidth.
|
|
|
|
If a sequence, the levels in ascending order will be plotted with
|
|
the linewidths in the order specified.
|
|
|
|
If None, this falls back to :rc:`lines.linewidth`.
|
|
|
|
linestyles : {*None*, 'solid', 'dashed', 'dashdot', 'dotted'}, optional
|
|
*Only applies to* `.contour`.
|
|
|
|
If *linestyles* is *None*, the default is 'solid' unless the lines are
|
|
monochrome. In that case, negative contours will instead take their
|
|
linestyle from the *negative_linestyles* argument.
|
|
|
|
*linestyles* can also be an iterable of the above strings specifying a set
|
|
of linestyles to be used. If this iterable is shorter than the number of
|
|
contour levels it will be repeated as necessary.
|
|
|
|
negative_linestyles : {*None*, 'solid', 'dashed', 'dashdot', 'dotted'}, \
|
|
optional
|
|
*Only applies to* `.contour`.
|
|
|
|
If *linestyles* is *None* and the lines are monochrome, this argument
|
|
specifies the line style for negative contours.
|
|
|
|
If *negative_linestyles* is *None*, the default is taken from
|
|
:rc:`contour.negative_linestyles`.
|
|
|
|
*negative_linestyles* can also be an iterable of the above strings
|
|
specifying a set of linestyles to be used. If this iterable is shorter than
|
|
the number of contour levels it will be repeated as necessary.
|
|
|
|
hatches : list[str], optional
|
|
*Only applies to* `.contourf`.
|
|
|
|
A list of cross hatch patterns to use on the filled areas.
|
|
If None, no hatching will be added to the contour.
|
|
Hatching is supported in the PostScript, PDF, SVG and Agg
|
|
backends only.
|
|
|
|
algorithm : {'mpl2005', 'mpl2014', 'serial', 'threaded'}, optional
|
|
Which contouring algorithm to use to calculate the contour lines and
|
|
polygons. The algorithms are implemented in
|
|
`ContourPy <https://github.com/contourpy/contourpy>`_, consult the
|
|
`ContourPy documentation <https://contourpy.readthedocs.io>`_ for
|
|
further information.
|
|
|
|
The default is taken from :rc:`contour.algorithm`.
|
|
|
|
clip_path : `~matplotlib.patches.Patch` or `.Path` or `.TransformedPath`
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Set the clip path. See `~matplotlib.artist.Artist.set_clip_path`.
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.. versionadded:: 3.8
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data : indexable object, optional
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DATA_PARAMETER_PLACEHOLDER
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Notes
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-----
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1. `.contourf` differs from the MATLAB version in that it does not draw
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the polygon edges. To draw edges, add line contours with calls to
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`.contour`.
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2. `.contourf` fills intervals that are closed at the top; that is, for
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boundaries *z1* and *z2*, the filled region is::
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z1 < Z <= z2
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except for the lowest interval, which is closed on both sides (i.e.
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it includes the lowest value).
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3. `.contour` and `.contourf` use a `marching squares
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<https://en.wikipedia.org/wiki/Marching_squares>`_ algorithm to
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compute contour locations. More information can be found in
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`ContourPy documentation <https://contourpy.readthedocs.io>`_.
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""" % _docstring.interpd.params)
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