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basabuuka_prototyp/venv/lib/python3.5/site-packages/matplotlib/axis.py

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"""
Classes for the ticks and x and y axis
"""
import datetime
import logging
import warnings
import numpy as np
from matplotlib import rcParams
import matplotlib.artist as artist
from matplotlib.artist import allow_rasterization
import matplotlib.cbook as cbook
from matplotlib.cbook import _string_to_bool
import matplotlib.font_manager as font_manager
import matplotlib.lines as mlines
import matplotlib.patches as mpatches
import matplotlib.scale as mscale
import matplotlib.text as mtext
import matplotlib.ticker as mticker
import matplotlib.transforms as mtransforms
import matplotlib.units as munits
_log = logging.getLogger(__name__)
GRIDLINE_INTERPOLATION_STEPS = 180
# This list is being used for compatibility with Axes.grid, which
# allows all Line2D kwargs.
_line_AI = artist.ArtistInspector(mlines.Line2D)
_line_param_names = _line_AI.get_setters()
_line_param_aliases = [list(d)[0] for d in _line_AI.aliasd.values()]
_gridline_param_names = ['grid_' + name
for name in _line_param_names + _line_param_aliases]
class Tick(artist.Artist):
"""
Abstract base class for the axis ticks, grid lines and labels
1 refers to the bottom of the plot for xticks and the left for yticks
2 refers to the top of the plot for xticks and the right for yticks
Attributes
----------
tick1line : Line2D
tick2line : Line2D
gridline : Line2D
label1 : Text
label2 : Text
gridOn : bool
Determines whether to draw the tickline.
tick1On : bool
Determines whether to draw the first tickline.
tick2On : bool
Determines whether to draw the second tickline.
label1On : bool
Determines whether to draw the first tick label.
label2On : bool
Determines whether to draw the second tick label.
"""
def __init__(self, axes, loc, label,
size=None, # points
width=None,
color=None,
tickdir=None,
pad=None,
labelsize=None,
labelcolor=None,
zorder=None,
gridOn=None, # defaults to axes.grid depending on
# axes.grid.which
tick1On=True,
tick2On=True,
label1On=True,
label2On=False,
major=True,
labelrotation=0,
grid_color=None,
grid_linestyle=None,
grid_linewidth=None,
grid_alpha=None,
**kw # Other Line2D kwargs applied to gridlines.
):
"""
bbox is the Bound2D bounding box in display coords of the Axes
loc is the tick location in data coords
size is the tick size in points
"""
artist.Artist.__init__(self)
if gridOn is None:
if major and (rcParams['axes.grid.which'] in ('both', 'major')):
gridOn = rcParams['axes.grid']
elif (not major) and (rcParams['axes.grid.which']
in ('both', 'minor')):
gridOn = rcParams['axes.grid']
else:
gridOn = False
self.set_figure(axes.figure)
self.axes = axes
name = self.__name__.lower()
self._name = name
self._loc = loc
if size is None:
if major:
size = rcParams['%s.major.size' % name]
else:
size = rcParams['%s.minor.size' % name]
self._size = size
if width is None:
if major:
width = rcParams['%s.major.width' % name]
else:
width = rcParams['%s.minor.width' % name]
self._width = width
if color is None:
color = rcParams['%s.color' % name]
self._color = color
if pad is None:
if major:
pad = rcParams['%s.major.pad' % name]
else:
pad = rcParams['%s.minor.pad' % name]
self._base_pad = pad
if labelcolor is None:
labelcolor = rcParams['%s.color' % name]
self._labelcolor = labelcolor
if labelsize is None:
labelsize = rcParams['%s.labelsize' % name]
self._labelsize = labelsize
self._set_labelrotation(labelrotation)
if zorder is None:
if major:
zorder = mlines.Line2D.zorder + 0.01
else:
zorder = mlines.Line2D.zorder
self._zorder = zorder
self._grid_color = (rcParams['grid.color']
if grid_color is None else grid_color)
self._grid_linestyle = (rcParams['grid.linestyle']
if grid_linestyle is None else grid_linestyle)
self._grid_linewidth = (rcParams['grid.linewidth']
if grid_linewidth is None else grid_linewidth)
self._grid_alpha = (rcParams['grid.alpha']
if grid_alpha is None else grid_alpha)
self._grid_kw = {k[5:]: v for k, v in kw.items()}
self.apply_tickdir(tickdir)
self.tick1line = self._get_tick1line()
self.tick2line = self._get_tick2line()
self.gridline = self._get_gridline()
self.label1 = self._get_text1()
self.label = self.label1 # legacy name
self.label2 = self._get_text2()
self.gridOn = gridOn
self.tick1On = tick1On
self.tick2On = tick2On
self.label1On = label1On
self.label2On = label2On
self.update_position(loc)
def _set_labelrotation(self, labelrotation):
if isinstance(labelrotation, str):
mode = labelrotation
angle = 0
elif isinstance(labelrotation, (tuple, list)):
mode, angle = labelrotation
else:
mode = 'default'
angle = labelrotation
if mode not in ('auto', 'default'):
raise ValueError("Label rotation mode must be 'default' or "
"'auto', not '{}'.".format(mode))
self._labelrotation = (mode, angle)
def apply_tickdir(self, tickdir):
"""
Calculate self._pad and self._tickmarkers
"""
pass
def get_tickdir(self):
return self._tickdir
def get_tick_padding(self):
"""
Get the length of the tick outside of the axes.
"""
padding = {
'in': 0.0,
'inout': 0.5,
'out': 1.0
}
return self._size * padding[self._tickdir]
def get_children(self):
children = [self.tick1line, self.tick2line,
self.gridline, self.label1, self.label2]
return children
def set_clip_path(self, clippath, transform=None):
artist.Artist.set_clip_path(self, clippath, transform)
self.gridline.set_clip_path(clippath, transform)
self.stale = True
set_clip_path.__doc__ = artist.Artist.set_clip_path.__doc__
def get_pad_pixels(self):
return self.figure.dpi * self._base_pad / 72
def contains(self, mouseevent):
"""
Test whether the mouse event occurred in the Tick marks.
This function always returns false. It is more useful to test if the
axis as a whole contains the mouse rather than the set of tick marks.
"""
if callable(self._contains):
return self._contains(self, mouseevent)
return False, {}
def set_pad(self, val):
"""
Set the tick label pad in points
Parameters
----------
val : float
"""
self._apply_params(pad=val)
self.stale = True
def get_pad(self):
'Get the value of the tick label pad in points'
return self._base_pad
def _get_text1(self):
'Get the default Text 1 instance'
pass
def _get_text2(self):
'Get the default Text 2 instance'
pass
def _get_tick1line(self):
'Get the default line2D instance for tick1'
pass
def _get_tick2line(self):
'Get the default line2D instance for tick2'
pass
def _get_gridline(self):
'Get the default grid Line2d instance for this tick'
pass
def get_loc(self):
'Return the tick location (data coords) as a scalar'
return self._loc
@allow_rasterization
def draw(self, renderer):
if not self.get_visible():
self.stale = False
return
renderer.open_group(self.__name__)
if self.gridOn:
self.gridline.draw(renderer)
if self.tick1On:
self.tick1line.draw(renderer)
if self.tick2On:
self.tick2line.draw(renderer)
if self.label1On:
self.label1.draw(renderer)
if self.label2On:
self.label2.draw(renderer)
renderer.close_group(self.__name__)
self.stale = False
def set_label1(self, s):
"""
Set the label1 text.
Parameters
----------
s : str
"""
self.label1.set_text(s)
self.stale = True
set_label = set_label1
def set_label2(self, s):
"""
Set the label2 text.
Parameters
----------
s : str
"""
self.label2.set_text(s)
self.stale = True
def _set_artist_props(self, a):
a.set_figure(self.figure)
def get_view_interval(self):
'return the view Interval instance for the axis this tick is ticking'
raise NotImplementedError('Derived must override')
def _apply_params(self, **kw):
for name in ['gridOn', 'tick1On', 'tick2On', 'label1On', 'label2On']:
if name in kw:
setattr(self, name, kw.pop(name))
if any(k in kw for k in ['size', 'width', 'pad', 'tickdir']):
self._size = kw.pop('size', self._size)
# Width could be handled outside this block, but it is
# convenient to leave it here.
self._width = kw.pop('width', self._width)
self._base_pad = kw.pop('pad', self._base_pad)
# apply_tickdir uses _size and _base_pad to make _pad,
# and also makes _tickmarkers.
self.apply_tickdir(kw.pop('tickdir', self._tickdir))
self.tick1line.set_marker(self._tickmarkers[0])
self.tick2line.set_marker(self._tickmarkers[1])
for line in (self.tick1line, self.tick2line):
line.set_markersize(self._size)
line.set_markeredgewidth(self._width)
# _get_text1_transform uses _pad from apply_tickdir.
trans = self._get_text1_transform()[0]
self.label1.set_transform(trans)
trans = self._get_text2_transform()[0]
self.label2.set_transform(trans)
tick_kw = {k: v for k, v in kw.items() if k in ['color', 'zorder']}
self.tick1line.set(**tick_kw)
self.tick2line.set(**tick_kw)
for k, v in tick_kw.items():
setattr(self, '_' + k, v)
if 'labelrotation' in kw:
self._set_labelrotation(kw.pop('labelrotation'))
self.label1.set(rotation=self._labelrotation[1])
self.label2.set(rotation=self._labelrotation[1])
label_kw = {k[5:]: v for k, v in kw.items()
if k in ['labelsize', 'labelcolor']}
self.label1.set(**label_kw)
self.label2.set(**label_kw)
for k, v in label_kw.items():
# for labelsize the text objects covert str ('small')
# -> points. grab the integer from the `Text` object
# instead of saving the string representation
v = getattr(self.label1, 'get_' + k)()
setattr(self, '_label' + k, v)
grid_kw = {k[5:]: v for k, v in kw.items()
if k in _gridline_param_names}
self.gridline.set(**grid_kw)
for k, v in grid_kw.items():
setattr(self, '_grid_' + k, v)
def update_position(self, loc):
'Set the location of tick in data coords with scalar *loc*'
raise NotImplementedError('Derived must override')
def _get_text1_transform(self):
raise NotImplementedError('Derived must override')
def _get_text2_transform(self):
raise NotImplementedError('Derived must override')
class XTick(Tick):
"""
Contains all the Artists needed to make an x tick - the tick line,
the label text and the grid line
"""
__name__ = 'xtick'
def _get_text1_transform(self):
return self.axes.get_xaxis_text1_transform(self._pad)
def _get_text2_transform(self):
return self.axes.get_xaxis_text2_transform(self._pad)
def apply_tickdir(self, tickdir):
if tickdir is None:
tickdir = rcParams['%s.direction' % self._name]
self._tickdir = tickdir
if self._tickdir == 'in':
self._tickmarkers = (mlines.TICKUP, mlines.TICKDOWN)
elif self._tickdir == 'inout':
self._tickmarkers = ('|', '|')
else:
self._tickmarkers = (mlines.TICKDOWN, mlines.TICKUP)
self._pad = self._base_pad + self.get_tick_padding()
self.stale = True
def _get_text1(self):
'Get the default Text instance'
# the y loc is 3 points below the min of y axis
# get the affine as an a,b,c,d,tx,ty list
# x in data coords, y in axes coords
trans, vert, horiz = self._get_text1_transform()
t = mtext.Text(
x=0, y=0,
fontproperties=font_manager.FontProperties(size=self._labelsize),
color=self._labelcolor,
verticalalignment=vert,
horizontalalignment=horiz,
)
t.set_transform(trans)
self._set_artist_props(t)
return t
def _get_text2(self):
'Get the default Text 2 instance'
# x in data coords, y in axes coords
trans, vert, horiz = self._get_text2_transform()
t = mtext.Text(
x=0, y=1,
fontproperties=font_manager.FontProperties(size=self._labelsize),
color=self._labelcolor,
verticalalignment=vert,
horizontalalignment=horiz,
)
t.set_transform(trans)
self._set_artist_props(t)
return t
def _get_tick1line(self):
'Get the default line2D instance'
# x in data coords, y in axes coords
l = mlines.Line2D(xdata=(0,), ydata=(0,), color=self._color,
linestyle='None', marker=self._tickmarkers[0],
markersize=self._size,
markeredgewidth=self._width, zorder=self._zorder)
l.set_transform(self.axes.get_xaxis_transform(which='tick1'))
self._set_artist_props(l)
return l
def _get_tick2line(self):
'Get the default line2D instance'
# x in data coords, y in axes coords
l = mlines.Line2D(xdata=(0,), ydata=(1,),
color=self._color,
linestyle='None',
marker=self._tickmarkers[1],
markersize=self._size,
markeredgewidth=self._width,
zorder=self._zorder)
l.set_transform(self.axes.get_xaxis_transform(which='tick2'))
self._set_artist_props(l)
return l
def _get_gridline(self):
'Get the default line2D instance'
# x in data coords, y in axes coords
l = mlines.Line2D(xdata=(0.0, 0.0), ydata=(0, 1.0),
color=self._grid_color,
linestyle=self._grid_linestyle,
linewidth=self._grid_linewidth,
alpha=self._grid_alpha,
markersize=0,
**self._grid_kw)
l.set_transform(self.axes.get_xaxis_transform(which='grid'))
l.get_path()._interpolation_steps = GRIDLINE_INTERPOLATION_STEPS
self._set_artist_props(l)
return l
def update_position(self, loc):
'Set the location of tick in data coords with scalar *loc*'
if self.tick1On:
self.tick1line.set_xdata((loc,))
if self.tick2On:
self.tick2line.set_xdata((loc,))
if self.gridOn:
self.gridline.set_xdata((loc,))
if self.label1On:
self.label1.set_x(loc)
if self.label2On:
self.label2.set_x(loc)
self._loc = loc
self.stale = True
def get_view_interval(self):
'return the Interval instance for this axis view limits'
return self.axes.viewLim.intervalx
class YTick(Tick):
"""
Contains all the Artists needed to make a Y tick - the tick line,
the label text and the grid line
"""
__name__ = 'ytick'
def _get_text1_transform(self):
return self.axes.get_yaxis_text1_transform(self._pad)
def _get_text2_transform(self):
return self.axes.get_yaxis_text2_transform(self._pad)
def apply_tickdir(self, tickdir):
if tickdir is None:
tickdir = rcParams['%s.direction' % self._name]
self._tickdir = tickdir
if self._tickdir == 'in':
self._tickmarkers = (mlines.TICKRIGHT, mlines.TICKLEFT)
elif self._tickdir == 'inout':
self._tickmarkers = ('_', '_')
else:
self._tickmarkers = (mlines.TICKLEFT, mlines.TICKRIGHT)
self._pad = self._base_pad + self.get_tick_padding()
self.stale = True
# how far from the y axis line the right of the ticklabel are
def _get_text1(self):
'Get the default Text instance'
# x in axes coords, y in data coords
trans, vert, horiz = self._get_text1_transform()
t = mtext.Text(
x=0, y=0,
fontproperties=font_manager.FontProperties(size=self._labelsize),
color=self._labelcolor,
verticalalignment=vert,
horizontalalignment=horiz,
)
t.set_transform(trans)
self._set_artist_props(t)
return t
def _get_text2(self):
'Get the default Text instance'
# x in axes coords, y in data coords
trans, vert, horiz = self._get_text2_transform()
t = mtext.Text(
x=1, y=0,
fontproperties=font_manager.FontProperties(size=self._labelsize),
color=self._labelcolor,
verticalalignment=vert,
horizontalalignment=horiz,
)
t.set_transform(trans)
self._set_artist_props(t)
return t
def _get_tick1line(self):
'Get the default line2D instance'
# x in axes coords, y in data coords
l = mlines.Line2D((0,), (0,),
color=self._color,
marker=self._tickmarkers[0],
linestyle='None',
markersize=self._size,
markeredgewidth=self._width,
zorder=self._zorder)
l.set_transform(self.axes.get_yaxis_transform(which='tick1'))
self._set_artist_props(l)
return l
def _get_tick2line(self):
'Get the default line2D instance'
# x in axes coords, y in data coords
l = mlines.Line2D((1,), (0,),
color=self._color,
marker=self._tickmarkers[1],
linestyle='None',
markersize=self._size,
markeredgewidth=self._width,
zorder=self._zorder)
l.set_transform(self.axes.get_yaxis_transform(which='tick2'))
self._set_artist_props(l)
return l
def _get_gridline(self):
'Get the default line2D instance'
# x in axes coords, y in data coords
l = mlines.Line2D(xdata=(0, 1), ydata=(0, 0),
color=self._grid_color,
linestyle=self._grid_linestyle,
linewidth=self._grid_linewidth,
alpha=self._grid_alpha,
markersize=0,
**self._grid_kw)
l.set_transform(self.axes.get_yaxis_transform(which='grid'))
l.get_path()._interpolation_steps = GRIDLINE_INTERPOLATION_STEPS
self._set_artist_props(l)
return l
def update_position(self, loc):
'Set the location of tick in data coords with scalar *loc*'
if self.tick1On:
self.tick1line.set_ydata((loc,))
if self.tick2On:
self.tick2line.set_ydata((loc,))
if self.gridOn:
self.gridline.set_ydata((loc,))
if self.label1On:
self.label1.set_y(loc)
if self.label2On:
self.label2.set_y(loc)
self._loc = loc
self.stale = True
def get_view_interval(self):
'return the Interval instance for this axis view limits'
return self.axes.viewLim.intervaly
class Ticker(object):
locator = None
formatter = None
class _LazyTickList(object):
"""
A descriptor for lazy instantiation of tick lists.
See comment above definition of the ``majorTicks`` and ``minorTicks``
attributes.
"""
def __init__(self, major):
self._major = major
def __get__(self, instance, cls):
if instance is None:
return self
else:
# instance._get_tick() can itself try to access the majorTicks
# attribute (e.g. in certain projection classes which override
# e.g. get_xaxis_text1_transform). In order to avoid infinite
# recursion, first set the majorTicks on the instance to an empty
# list, then create the tick and append it.
if self._major:
instance.majorTicks = []
tick = instance._get_tick(major=True)
instance.majorTicks.append(tick)
return instance.majorTicks
else:
instance.minorTicks = []
tick = instance._get_tick(major=False)
instance.minorTicks.append(tick)
return instance.minorTicks
class Axis(artist.Artist):
"""
Public attributes
* :attr:`axes.transData` - transform data coords to display coords
* :attr:`axes.transAxes` - transform axis coords to display coords
* :attr:`labelpad` - number of points between the axis and its label
"""
OFFSETTEXTPAD = 3
def __str__(self):
return self.__class__.__name__ \
+ "(%f,%f)" % tuple(self.axes.transAxes.transform_point((0, 0)))
def __init__(self, axes, pickradius=15):
"""
Init the axis with the parent Axes instance
"""
artist.Artist.__init__(self)
self.set_figure(axes.figure)
self.isDefault_label = True
self.axes = axes
self.major = Ticker()
self.minor = Ticker()
self.callbacks = cbook.CallbackRegistry()
self._autolabelpos = True
self._smart_bounds = False
self.label = self._get_label()
self.labelpad = rcParams['axes.labelpad']
self.offsetText = self._get_offset_text()
self.pickradius = pickradius
# Initialize here for testing; later add API
self._major_tick_kw = dict()
self._minor_tick_kw = dict()
self.cla()
self._set_scale('linear')
# During initialization, Axis objects often create ticks that are later
# unused; this turns out to be a very slow step. Instead, use a custom
# descriptor to make the tick lists lazy and instantiate them as needed.
majorTicks = _LazyTickList(major=True)
minorTicks = _LazyTickList(major=False)
def set_label_coords(self, x, y, transform=None):
"""
Set the coordinates of the label. By default, the x
coordinate of the y label is determined by the tick label
bounding boxes, but this can lead to poor alignment of
multiple ylabels if there are multiple axes. Ditto for the y
coordinate of the x label.
You can also specify the coordinate system of the label with
the transform. If None, the default coordinate system will be
the axes coordinate system (0,0) is (left,bottom), (0.5, 0.5)
is middle, etc
"""
self._autolabelpos = False
if transform is None:
transform = self.axes.transAxes
self.label.set_transform(transform)
self.label.set_position((x, y))
self.stale = True
def get_transform(self):
return self._scale.get_transform()
def get_scale(self):
return self._scale.name
def _set_scale(self, value, **kwargs):
self._scale = mscale.scale_factory(value, self, **kwargs)
self._scale.set_default_locators_and_formatters(self)
self.isDefault_majloc = True
self.isDefault_minloc = True
self.isDefault_majfmt = True
self.isDefault_minfmt = True
def limit_range_for_scale(self, vmin, vmax):
return self._scale.limit_range_for_scale(vmin, vmax, self.get_minpos())
@property
@cbook.deprecated("2.2.0")
def unit_data(self):
return self.units
@unit_data.setter
@cbook.deprecated("2.2.0")
def unit_data(self, unit_data):
self.set_units(unit_data)
def get_children(self):
children = [self.label, self.offsetText]
majorticks = self.get_major_ticks()
minorticks = self.get_minor_ticks()
children.extend(majorticks)
children.extend(minorticks)
return children
def cla(self):
'clear the current axis'
self.label.set_text('') # self.set_label_text would change isDefault_
self._set_scale('linear')
# Clear the callback registry for this axis, or it may "leak"
self.callbacks = cbook.CallbackRegistry()
# whether the grids are on
self._gridOnMajor = (rcParams['axes.grid'] and
rcParams['axes.grid.which'] in ('both', 'major'))
self._gridOnMinor = (rcParams['axes.grid'] and
rcParams['axes.grid.which'] in ('both', 'minor'))
self.reset_ticks()
self.converter = None
self.units = None
self.set_units(None)
self.stale = True
def reset_ticks(self):
"""
Re-initialize the major and minor Tick lists.
Each list starts with a single fresh Tick.
"""
# Restore the lazy tick lists.
try:
del self.majorTicks
except AttributeError:
pass
try:
del self.minorTicks
except AttributeError:
pass
try:
self.set_clip_path(self.axes.patch)
except AttributeError:
pass
def set_tick_params(self, which='major', reset=False, **kw):
"""
Set appearance parameters for ticks, ticklabels, and gridlines.
For documentation of keyword arguments, see
:meth:`matplotlib.axes.Axes.tick_params`.
"""
dicts = []
if which == 'major' or which == 'both':
dicts.append(self._major_tick_kw)
if which == 'minor' or which == 'both':
dicts.append(self._minor_tick_kw)
kwtrans = self._translate_tick_kw(kw, to_init_kw=True)
for d in dicts:
if reset:
d.clear()
d.update(kwtrans)
if reset:
self.reset_ticks()
else:
if which == 'major' or which == 'both':
for tick in self.majorTicks:
tick._apply_params(**self._major_tick_kw)
if which == 'minor' or which == 'both':
for tick in self.minorTicks:
tick._apply_params(**self._minor_tick_kw)
if 'labelcolor' in kwtrans:
self.offsetText.set_color(kwtrans['labelcolor'])
self.stale = True
@staticmethod
def _translate_tick_kw(kw, to_init_kw=True):
# The following lists may be moved to a more
# accessible location.
kwkeys0 = ['size', 'width', 'color', 'tickdir', 'pad',
'labelsize', 'labelcolor', 'zorder', 'gridOn',
'tick1On', 'tick2On', 'label1On', 'label2On']
kwkeys1 = ['length', 'direction', 'left', 'bottom', 'right', 'top',
'labelleft', 'labelbottom', 'labelright', 'labeltop',
'labelrotation']
kwkeys2 = _gridline_param_names
kwkeys = kwkeys0 + kwkeys1 + kwkeys2
kwtrans = dict()
if to_init_kw:
if 'length' in kw:
kwtrans['size'] = kw.pop('length')
if 'direction' in kw:
kwtrans['tickdir'] = kw.pop('direction')
if 'rotation' in kw:
kwtrans['labelrotation'] = kw.pop('rotation')
if 'left' in kw:
kwtrans['tick1On'] = _string_to_bool(kw.pop('left'))
if 'bottom' in kw:
kwtrans['tick1On'] = _string_to_bool(kw.pop('bottom'))
if 'right' in kw:
kwtrans['tick2On'] = _string_to_bool(kw.pop('right'))
if 'top' in kw:
kwtrans['tick2On'] = _string_to_bool(kw.pop('top'))
if 'labelleft' in kw:
kwtrans['label1On'] = _string_to_bool(kw.pop('labelleft'))
if 'labelbottom' in kw:
kwtrans['label1On'] = _string_to_bool(kw.pop('labelbottom'))
if 'labelright' in kw:
kwtrans['label2On'] = _string_to_bool(kw.pop('labelright'))
if 'labeltop' in kw:
kwtrans['label2On'] = _string_to_bool(kw.pop('labeltop'))
if 'colors' in kw:
c = kw.pop('colors')
kwtrans['color'] = c
kwtrans['labelcolor'] = c
# Maybe move the checking up to the caller of this method.
for key in kw:
if key not in kwkeys:
raise ValueError(
"keyword %s is not recognized; valid keywords are %s"
% (key, kwkeys))
kwtrans.update(kw)
else:
raise NotImplementedError("Inverse translation is deferred")
return kwtrans
def set_clip_path(self, clippath, transform=None):
artist.Artist.set_clip_path(self, clippath, transform)
for child in self.majorTicks + self.minorTicks:
child.set_clip_path(clippath, transform)
self.stale = True
def get_view_interval(self):
'return the Interval instance for this axis view limits'
raise NotImplementedError('Derived must override')
def set_view_interval(self, vmin, vmax, ignore=False):
raise NotImplementedError('Derived must override')
def get_data_interval(self):
'return the Interval instance for this axis data limits'
raise NotImplementedError('Derived must override')
def set_data_interval(self):
'''set the axis data limits'''
raise NotImplementedError('Derived must override')
def set_default_intervals(self):
'''set the default limits for the axis data and view interval if they
are not mutated'''
# this is mainly in support of custom object plotting. For
# example, if someone passes in a datetime object, we do not
# know automagically how to set the default min/max of the
# data and view limits. The unit conversion AxisInfo
# interface provides a hook for custom types to register
# default limits through the AxisInfo.default_limits
# attribute, and the derived code below will check for that
# and use it if is available (else just use 0..1)
pass
def _set_artist_props(self, a):
if a is None:
return
a.set_figure(self.figure)
def iter_ticks(self):
"""
Iterate through all of the major and minor ticks.
"""
majorLocs = self.major.locator()
majorTicks = self.get_major_ticks(len(majorLocs))
self.major.formatter.set_locs(majorLocs)
majorLabels = [self.major.formatter(val, i)
for i, val in enumerate(majorLocs)]
minorLocs = self.minor.locator()
minorTicks = self.get_minor_ticks(len(minorLocs))
self.minor.formatter.set_locs(minorLocs)
minorLabels = [self.minor.formatter(val, i)
for i, val in enumerate(minorLocs)]
major_minor = [
(majorTicks, majorLocs, majorLabels),
(minorTicks, minorLocs, minorLabels)]
for group in major_minor:
yield from zip(*group)
def get_ticklabel_extents(self, renderer):
"""
Get the extents of the tick labels on either side
of the axes.
"""
ticks_to_draw = self._update_ticks(renderer)
ticklabelBoxes, ticklabelBoxes2 = self._get_tick_bboxes(ticks_to_draw,
renderer)
if len(ticklabelBoxes):
bbox = mtransforms.Bbox.union(ticklabelBoxes)
else:
bbox = mtransforms.Bbox.from_extents(0, 0, 0, 0)
if len(ticklabelBoxes2):
bbox2 = mtransforms.Bbox.union(ticklabelBoxes2)
else:
bbox2 = mtransforms.Bbox.from_extents(0, 0, 0, 0)
return bbox, bbox2
def set_smart_bounds(self, value):
"""set the axis to have smart bounds"""
self._smart_bounds = value
self.stale = True
def get_smart_bounds(self):
"""get whether the axis has smart bounds"""
return self._smart_bounds
def _update_ticks(self, renderer):
"""
Update ticks (position and labels) using the current data
interval of the axes. Returns a list of ticks that will be
drawn.
"""
interval = self.get_view_interval()
tick_tups = list(self.iter_ticks()) # iter_ticks calls the locator
if self._smart_bounds and tick_tups:
# handle inverted limits
view_low, view_high = sorted(interval)
data_low, data_high = sorted(self.get_data_interval())
locs = np.sort([ti[1] for ti in tick_tups])
if data_low <= view_low:
# data extends beyond view, take view as limit
ilow = view_low
else:
# data stops within view, take best tick
good_locs = locs[locs <= data_low]
if len(good_locs):
# last tick prior or equal to first data point
ilow = good_locs[-1]
else:
# No ticks (why not?), take first tick
ilow = locs[0]
if data_high >= view_high:
# data extends beyond view, take view as limit
ihigh = view_high
else:
# data stops within view, take best tick
good_locs = locs[locs >= data_high]
if len(good_locs):
# first tick after or equal to last data point
ihigh = good_locs[0]
else:
# No ticks (why not?), take last tick
ihigh = locs[-1]
tick_tups = [ti for ti in tick_tups if ilow <= ti[1] <= ihigh]
# so that we don't lose ticks on the end, expand out the interval ever
# so slightly. The "ever so slightly" is defined to be the width of a
# half of a pixel. We don't want to draw a tick that even one pixel
# outside of the defined axis interval.
if interval[0] <= interval[1]:
interval_expanded = interval
else:
interval_expanded = interval[1], interval[0]
if hasattr(self, '_get_pixel_distance_along_axis'):
# normally, one does not want to catch all exceptions that
# could possibly happen, but it is not clear exactly what
# exceptions might arise from a user's projection (their
# rendition of the Axis object). So, we catch all, with
# the idea that one would rather potentially lose a tick
# from one side of the axis or another, rather than see a
# stack trace.
# We also catch users warnings here. These are the result of
# invalid numpy calculations that may be the result of out of
# bounds on axis with finite allowed intervals such as geo
# projections i.e. Mollweide.
with np.errstate(invalid='ignore'):
try:
ds1 = self._get_pixel_distance_along_axis(
interval_expanded[0], -0.5)
except:
warnings.warn("Unable to find pixel distance along axis "
"for interval padding of ticks; assuming no "
"interval padding needed.")
ds1 = 0.0
if np.isnan(ds1):
ds1 = 0.0
try:
ds2 = self._get_pixel_distance_along_axis(
interval_expanded[1], +0.5)
except:
warnings.warn("Unable to find pixel distance along axis "
"for interval padding of ticks; assuming no "
"interval padding needed.")
ds2 = 0.0
if np.isnan(ds2):
ds2 = 0.0
interval_expanded = (interval_expanded[0] - ds1,
interval_expanded[1] + ds2)
ticks_to_draw = []
for tick, loc, label in tick_tups:
if tick is None:
continue
# NB: always update labels and position to avoid issues like #9397
tick.update_position(loc)
tick.set_label1(label)
tick.set_label2(label)
if not mtransforms.interval_contains(interval_expanded, loc):
continue
ticks_to_draw.append(tick)
return ticks_to_draw
def _get_tick_bboxes(self, ticks, renderer):
"""
Given the list of ticks, return two lists of bboxes. One for
tick lable1's and another for tick label2's.
"""
ticklabelBoxes = []
ticklabelBoxes2 = []
for tick in ticks:
if tick.label1On and tick.label1.get_visible():
extent = tick.label1.get_window_extent(renderer)
ticklabelBoxes.append(extent)
if tick.label2On and tick.label2.get_visible():
extent = tick.label2.get_window_extent(renderer)
ticklabelBoxes2.append(extent)
return ticklabelBoxes, ticklabelBoxes2
def get_tightbbox(self, renderer):
"""
Return a bounding box that encloses the axis. It only accounts
tick labels, axis label, and offsetText.
"""
if not self.get_visible():
return
ticks_to_draw = self._update_ticks(renderer)
self._update_label_position(renderer)
# go back to just this axis's tick labels
ticklabelBoxes, ticklabelBoxes2 = self._get_tick_bboxes(
ticks_to_draw, renderer)
self._update_offset_text_position(ticklabelBoxes, ticklabelBoxes2)
self.offsetText.set_text(self.major.formatter.get_offset())
bb = []
for a in [self.label, self.offsetText]:
bbox = a.get_window_extent(renderer)
if (np.isfinite(bbox.width) and np.isfinite(bbox.height) and
a.get_visible()):
bb.append(bbox)
bb.extend(ticklabelBoxes)
bb.extend(ticklabelBoxes2)
bb = [b for b in bb if b.width != 0 or b.height != 0]
if bb:
_bbox = mtransforms.Bbox.union(bb)
return _bbox
else:
return None
def get_tick_padding(self):
values = []
if len(self.majorTicks):
values.append(self.majorTicks[0].get_tick_padding())
if len(self.minorTicks):
values.append(self.minorTicks[0].get_tick_padding())
return max(values, default=0)
@allow_rasterization
def draw(self, renderer, *args, **kwargs):
'Draw the axis lines, grid lines, tick lines and labels'
if not self.get_visible():
return
renderer.open_group(__name__)
ticks_to_draw = self._update_ticks(renderer)
ticklabelBoxes, ticklabelBoxes2 = self._get_tick_bboxes(ticks_to_draw,
renderer)
for tick in ticks_to_draw:
tick.draw(renderer)
# scale up the axis label box to also find the neighbors, not
# just the tick labels that actually overlap note we need a
# *copy* of the axis label box because we don't wan't to scale
# the actual bbox
self._update_label_position(renderer)
self.label.draw(renderer)
self._update_offset_text_position(ticklabelBoxes, ticklabelBoxes2)
self.offsetText.set_text(self.major.formatter.get_offset())
self.offsetText.draw(renderer)
if 0: # draw the bounding boxes around the text for debug
for tick in self.majorTicks:
label = tick.label1
mpatches.bbox_artist(label, renderer)
mpatches.bbox_artist(self.label, renderer)
renderer.close_group(__name__)
self.stale = False
def _get_label(self):
raise NotImplementedError('Derived must override')
def _get_offset_text(self):
raise NotImplementedError('Derived must override')
def get_gridlines(self):
'Return the grid lines as a list of Line2D instance'
ticks = self.get_major_ticks()
return cbook.silent_list('Line2D gridline',
[tick.gridline for tick in ticks])
def get_label(self):
'Return the axis label as a Text instance'
return self.label
def get_offset_text(self):
'Return the axis offsetText as a Text instance'
return self.offsetText
def get_pickradius(self):
'Return the depth of the axis used by the picker'
return self.pickradius
def get_majorticklabels(self):
'Return a list of Text instances for the major ticklabels'
ticks = self.get_major_ticks()
labels1 = [tick.label1 for tick in ticks if tick.label1On]
labels2 = [tick.label2 for tick in ticks if tick.label2On]
return cbook.silent_list('Text major ticklabel', labels1 + labels2)
def get_minorticklabels(self):
'Return a list of Text instances for the minor ticklabels'
ticks = self.get_minor_ticks()
labels1 = [tick.label1 for tick in ticks if tick.label1On]
labels2 = [tick.label2 for tick in ticks if tick.label2On]
return cbook.silent_list('Text minor ticklabel', labels1 + labels2)
def get_ticklabels(self, minor=False, which=None):
"""
Get the tick labels as a list of :class:`~matplotlib.text.Text`
instances.
Parameters
----------
minor : bool
If True return the minor ticklabels,
else return the major ticklabels
which : None, ('minor', 'major', 'both')
Overrides `minor`.
Selects which ticklabels to return
Returns
-------
ret : list
List of :class:`~matplotlib.text.Text` instances.
"""
if which is not None:
if which == 'minor':
return self.get_minorticklabels()
elif which == 'major':
return self.get_majorticklabels()
elif which == 'both':
return self.get_majorticklabels() + self.get_minorticklabels()
else:
raise ValueError("`which` must be one of ('minor', 'major', "
"'both') not " + str(which))
if minor:
return self.get_minorticklabels()
return self.get_majorticklabels()
def get_majorticklines(self):
'Return the major tick lines as a list of Line2D instances'
lines = []
ticks = self.get_major_ticks()
for tick in ticks:
lines.append(tick.tick1line)
lines.append(tick.tick2line)
return cbook.silent_list('Line2D ticklines', lines)
def get_minorticklines(self):
'Return the minor tick lines as a list of Line2D instances'
lines = []
ticks = self.get_minor_ticks()
for tick in ticks:
lines.append(tick.tick1line)
lines.append(tick.tick2line)
return cbook.silent_list('Line2D ticklines', lines)
def get_ticklines(self, minor=False):
'Return the tick lines as a list of Line2D instances'
if minor:
return self.get_minorticklines()
return self.get_majorticklines()
def get_majorticklocs(self):
"Get the major tick locations in data coordinates as a numpy array"
return self.major.locator()
def get_minorticklocs(self):
"Get the minor tick locations in data coordinates as a numpy array"
return self.minor.locator()
def get_ticklocs(self, minor=False):
"Get the tick locations in data coordinates as a numpy array"
if minor:
return self.minor.locator()
return self.major.locator()
def get_ticks_direction(self, minor=False):
"""
Get the tick directions as a numpy array
Parameters
----------
minor : boolean
True to return the minor tick directions,
False to return the major tick directions,
Default is False
Returns
-------
numpy array of tick directions
"""
if minor:
return np.array(
[tick._tickdir for tick in self.get_minor_ticks()])
else:
return np.array(
[tick._tickdir for tick in self.get_major_ticks()])
def _get_tick(self, major):
'return the default tick instance'
raise NotImplementedError('derived must override')
def _copy_tick_props(self, src, dest):
'Copy the props from src tick to dest tick'
if src is None or dest is None:
return
dest.label1.update_from(src.label1)
dest.label2.update_from(src.label2)
dest.tick1line.update_from(src.tick1line)
dest.tick2line.update_from(src.tick2line)
dest.gridline.update_from(src.gridline)
dest.tick1On = src.tick1On
dest.tick2On = src.tick2On
dest.label1On = src.label1On
dest.label2On = src.label2On
def get_label_text(self):
'Get the text of the label'
return self.label.get_text()
def get_major_locator(self):
'Get the locator of the major ticker'
return self.major.locator
def get_minor_locator(self):
'Get the locator of the minor ticker'
return self.minor.locator
def get_major_formatter(self):
'Get the formatter of the major ticker'
return self.major.formatter
def get_minor_formatter(self):
'Get the formatter of the minor ticker'
return self.minor.formatter
def get_major_ticks(self, numticks=None):
'get the tick instances; grow as necessary'
if numticks is None:
numticks = len(self.get_major_locator()())
while len(self.majorTicks) < numticks:
# update the new tick label properties from the old
tick = self._get_tick(major=True)
self.majorTicks.append(tick)
if self._gridOnMajor:
tick.gridOn = True
self._copy_tick_props(self.majorTicks[0], tick)
return self.majorTicks[:numticks]
def get_minor_ticks(self, numticks=None):
'get the minor tick instances; grow as necessary'
if numticks is None:
numticks = len(self.get_minor_locator()())
while len(self.minorTicks) < numticks:
# update the new tick label properties from the old
tick = self._get_tick(major=False)
self.minorTicks.append(tick)
if self._gridOnMinor:
tick.gridOn = True
self._copy_tick_props(self.minorTicks[0], tick)
return self.minorTicks[:numticks]
def grid(self, b=None, which='major', **kwargs):
"""
Configure the grid lines.
Parameters
----------
b : bool or None
Whether to show the grid lines. If any *kwargs* are supplied,
it is assumed you want the grid on and *b* will be set to True.
If *b* is *None* and there are no *kwargs*, this toggles the
visibility of the lines.
which : {'major', 'minor', 'both'}
The grid lines to apply the changes on.
**kwargs : `.Line2D` properties
Define the line properties of the grid, e.g.::
grid(color='r', linestyle='-', linewidth=2)
"""
if len(kwargs):
b = True
which = which.lower()
gridkw = {'grid_' + item[0]: item[1] for item in kwargs.items()}
if which in ['minor', 'both']:
if b is None:
self._gridOnMinor = not self._gridOnMinor
else:
self._gridOnMinor = b
self.set_tick_params(which='minor', gridOn=self._gridOnMinor,
**gridkw)
if which in ['major', 'both']:
if b is None:
self._gridOnMajor = not self._gridOnMajor
else:
self._gridOnMajor = b
self.set_tick_params(which='major', gridOn=self._gridOnMajor,
**gridkw)
self.stale = True
def update_units(self, data):
"""
introspect *data* for units converter and update the
axis.converter instance if necessary. Return *True*
if *data* is registered for unit conversion.
"""
converter = munits.registry.get_converter(data)
if converter is None:
return False
neednew = self.converter != converter
self.converter = converter
default = self.converter.default_units(data, self)
if default is not None and self.units is None:
self.set_units(default)
if neednew:
self._update_axisinfo()
self.stale = True
return True
def _update_axisinfo(self):
"""
check the axis converter for the stored units to see if the
axis info needs to be updated
"""
if self.converter is None:
return
info = self.converter.axisinfo(self.units, self)
if info is None:
return
if info.majloc is not None and \
self.major.locator != info.majloc and self.isDefault_majloc:
self.set_major_locator(info.majloc)
self.isDefault_majloc = True
if info.minloc is not None and \
self.minor.locator != info.minloc and self.isDefault_minloc:
self.set_minor_locator(info.minloc)
self.isDefault_minloc = True
if info.majfmt is not None and \
self.major.formatter != info.majfmt and self.isDefault_majfmt:
self.set_major_formatter(info.majfmt)
self.isDefault_majfmt = True
if info.minfmt is not None and \
self.minor.formatter != info.minfmt and self.isDefault_minfmt:
self.set_minor_formatter(info.minfmt)
self.isDefault_minfmt = True
if info.label is not None and self.isDefault_label:
self.set_label_text(info.label)
self.isDefault_label = True
self.set_default_intervals()
def have_units(self):
return self.converter is not None or self.units is not None
def convert_units(self, x):
# If x is already a number, doesn't need converting
if munits.ConversionInterface.is_numlike(x):
return x
if self.converter is None:
self.converter = munits.registry.get_converter(x)
if self.converter is None:
return x
ret = self.converter.convert(x, self.units, self)
return ret
def set_units(self, u):
"""
set the units for axis
ACCEPTS: a units tag
"""
pchanged = False
if u is None:
self.units = None
pchanged = True
else:
if u != self.units:
self.units = u
pchanged = True
if pchanged:
self._update_axisinfo()
self.callbacks.process('units')
self.callbacks.process('units finalize')
self.stale = True
def get_units(self):
'return the units for axis'
return self.units
def set_label_text(self, label, fontdict=None, **kwargs):
"""
Set the text value of the axis label.
ACCEPTS: A string value for the label
"""
self.isDefault_label = False
self.label.set_text(label)
if fontdict is not None:
self.label.update(fontdict)
self.label.update(kwargs)
self.stale = True
return self.label
def set_major_formatter(self, formatter):
"""
Set the formatter of the major ticker.
Parameters
----------
formatter : ~matplotlib.ticker.Formatter
"""
if not isinstance(formatter, mticker.Formatter):
raise TypeError("formatter argument should be instance of "
"matplotlib.ticker.Formatter")
self.isDefault_majfmt = False
self.major.formatter = formatter
formatter.set_axis(self)
self.stale = True
def set_minor_formatter(self, formatter):
"""
Set the formatter of the minor ticker.
Parameters
----------
formatter : ~matplotlib.ticker.Formatter
"""
if not isinstance(formatter, mticker.Formatter):
raise TypeError("formatter argument should be instance of "
"matplotlib.ticker.Formatter")
self.isDefault_minfmt = False
self.minor.formatter = formatter
formatter.set_axis(self)
self.stale = True
def set_major_locator(self, locator):
"""
Set the locator of the major ticker.
Parameters
----------
locator : ~matplotlib.ticker.Locator
"""
if not isinstance(locator, mticker.Locator):
raise TypeError("formatter argument should be instance of "
"matplotlib.ticker.Locator")
self.isDefault_majloc = False
self.major.locator = locator
locator.set_axis(self)
self.stale = True
def set_minor_locator(self, locator):
"""
Set the locator of the minor ticker.
Parameters
----------
locator : ~matplotlib.ticker.Locator
"""
if not isinstance(locator, mticker.Locator):
raise TypeError("formatter argument should be instance of "
"matplotlib.ticker.Locator")
self.isDefault_minloc = False
self.minor.locator = locator
locator.set_axis(self)
self.stale = True
def set_pickradius(self, pickradius):
"""
Set the depth of the axis used by the picker.
Parameters
----------
pickradius : float
"""
self.pickradius = pickradius
def set_ticklabels(self, ticklabels, *args, minor=False, **kwargs):
"""
Set the text values of the tick labels. Return a list of Text
instances. Use *kwarg* *minor=True* to select minor ticks.
All other kwargs are used to update the text object properties.
As for get_ticklabels, label1 (left or bottom) is
affected for a given tick only if its label1On attribute
is True, and similarly for label2. The list of returned
label text objects consists of all such label1 objects followed
by all such label2 objects.
The input *ticklabels* is assumed to match the set of
tick locations, regardless of the state of label1On and
label2On.
ACCEPTS: sequence of strings or Text objects
"""
get_labels = []
for t in ticklabels:
# try calling get_text() to check whether it is Text object
# if it is Text, get label content
try:
get_labels.append(t.get_text())
# otherwise add the label to the list directly
except AttributeError:
get_labels.append(t)
# replace the ticklabels list with the processed one
ticklabels = get_labels
if minor:
self.set_minor_formatter(mticker.FixedFormatter(ticklabels))
ticks = self.get_minor_ticks()
else:
self.set_major_formatter(mticker.FixedFormatter(ticklabels))
ticks = self.get_major_ticks()
ret = []
for tick_label, tick in zip(ticklabels, ticks):
# deal with label1
tick.label1.set_text(tick_label)
tick.label1.update(kwargs)
# deal with label2
tick.label2.set_text(tick_label)
tick.label2.update(kwargs)
# only return visible tick labels
if tick.label1On:
ret.append(tick.label1)
if tick.label2On:
ret.append(tick.label2)
self.stale = True
return ret
def set_ticks(self, ticks, minor=False):
"""
Set the locations of the tick marks from sequence ticks
ACCEPTS: sequence of floats
"""
# XXX if the user changes units, the information will be lost here
ticks = self.convert_units(ticks)
if len(ticks) > 1:
xleft, xright = self.get_view_interval()
if xright > xleft:
self.set_view_interval(min(ticks), max(ticks))
else:
self.set_view_interval(max(ticks), min(ticks))
if minor:
self.set_minor_locator(mticker.FixedLocator(ticks))
return self.get_minor_ticks(len(ticks))
else:
self.set_major_locator(mticker.FixedLocator(ticks))
return self.get_major_ticks(len(ticks))
def _get_tick_boxes_siblings(self, xdir, renderer):
"""
Get the bounding boxes for this `.axis` and its siblings
as set by `.Figure.align_xlabels` or `.Figure.align_ylablels`.
By default it just gets bboxes for self.
"""
raise NotImplementedError('Derived must override')
def _update_label_position(self, renderer):
"""
Update the label position based on the bounding box enclosing
all the ticklabels and axis spine
"""
raise NotImplementedError('Derived must override')
def _update_offset_text_position(self, bboxes, bboxes2):
"""
Update the label position based on the sequence of bounding
boxes of all the ticklabels
"""
raise NotImplementedError('Derived must override')
def pan(self, numsteps):
'Pan *numsteps* (can be positive or negative)'
self.major.locator.pan(numsteps)
def zoom(self, direction):
"Zoom in/out on axis; if *direction* is >0 zoom in, else zoom out"
self.major.locator.zoom(direction)
def axis_date(self, tz=None):
"""
Sets up x-axis ticks and labels that treat the x data as dates.
*tz* is a :class:`tzinfo` instance or a timezone string.
This timezone is used to create date labels.
"""
# By providing a sample datetime instance with the desired timezone,
# the registered converter can be selected, and the "units" attribute,
# which is the timezone, can be set.
if isinstance(tz, str):
import dateutil.tz
tz = dateutil.tz.gettz(tz)
self.update_units(datetime.datetime(2009, 1, 1, 0, 0, 0, 0, tz))
def get_tick_space(self):
"""
Return the estimated number of ticks that can fit on the axis.
"""
# Must be overridden in the subclass
raise NotImplementedError()
def get_label_position(self):
"""
Return the label position (top or bottom)
"""
return self.label_position
def set_label_position(self, position):
"""
Set the label position (top or bottom)
Parameters
----------
position : {'top', 'bottom'}
"""
raise NotImplementedError()
def get_minpos(self):
raise NotImplementedError()
class XAxis(Axis):
__name__ = 'xaxis'
axis_name = 'x'
def contains(self, mouseevent):
"""Test whether the mouse event occurred in the x axis.
"""
if callable(self._contains):
return self._contains(self, mouseevent)
x, y = mouseevent.x, mouseevent.y
try:
trans = self.axes.transAxes.inverted()
xaxes, yaxes = trans.transform_point((x, y))
except ValueError:
return False, {}
l, b = self.axes.transAxes.transform_point((0, 0))
r, t = self.axes.transAxes.transform_point((1, 1))
inaxis = 0 <= xaxes <= 1 and (
b - self.pickradius < y < b or
t < y < t + self.pickradius)
return inaxis, {}
def _get_tick(self, major):
if major:
tick_kw = self._major_tick_kw
else:
tick_kw = self._minor_tick_kw
return XTick(self.axes, 0, '', major=major, **tick_kw)
def _get_label(self):
# x in axes coords, y in display coords (to be updated at draw
# time by _update_label_positions)
label = mtext.Text(x=0.5, y=0,
fontproperties=font_manager.FontProperties(
size=rcParams['axes.labelsize'],
weight=rcParams['axes.labelweight']),
color=rcParams['axes.labelcolor'],
verticalalignment='top',
horizontalalignment='center')
label.set_transform(mtransforms.blended_transform_factory(
self.axes.transAxes, mtransforms.IdentityTransform()))
self._set_artist_props(label)
self.label_position = 'bottom'
return label
def _get_offset_text(self):
# x in axes coords, y in display coords (to be updated at draw time)
offsetText = mtext.Text(x=1, y=0,
fontproperties=font_manager.FontProperties(
size=rcParams['xtick.labelsize']),
color=rcParams['xtick.color'],
verticalalignment='top',
horizontalalignment='right')
offsetText.set_transform(mtransforms.blended_transform_factory(
self.axes.transAxes, mtransforms.IdentityTransform())
)
self._set_artist_props(offsetText)
self.offset_text_position = 'bottom'
return offsetText
def _get_pixel_distance_along_axis(self, where, perturb):
"""
Returns the amount, in data coordinates, that a single pixel
corresponds to in the locality given by "where", which is also given
in data coordinates, and is an x coordinate. "perturb" is the amount
to perturb the pixel. Usually +0.5 or -0.5.
Implementing this routine for an axis is optional; if present, it will
ensure that no ticks are lost due to round-off at the extreme ends of
an axis.
"""
# Note that this routine does not work for a polar axis, because of
# the 1e-10 below. To do things correctly, we need to use rmax
# instead of 1e-10 for a polar axis. But since we do not have that
# kind of information at this point, we just don't try to pad anything
# for the theta axis of a polar plot.
if self.axes.name == 'polar':
return 0.0
#
# first figure out the pixel location of the "where" point. We use
# 1e-10 for the y point, so that we remain compatible with log axes.
# transformation from data coords to display coords
trans = self.axes.transData
# transformation from display coords to data coords
transinv = trans.inverted()
pix = trans.transform_point((where, 1e-10))
# perturb the pixel
ptp = transinv.transform_point((pix[0] + perturb, pix[1]))
dx = abs(ptp[0] - where)
return dx
def set_label_position(self, position):
"""
Set the label position (top or bottom)
Parameters
----------
position : {'top', 'bottom'}
"""
if position == 'top':
self.label.set_verticalalignment('baseline')
elif position == 'bottom':
self.label.set_verticalalignment('top')
else:
raise ValueError("Position accepts only 'top' or 'bottom'")
self.label_position = position
self.stale = True
def _get_tick_boxes_siblings(self, renderer):
"""
Get the bounding boxes for this `.axis` and its siblings
as set by `.Figure.align_xlabels` or `.Figure.align_ylablels`.
By default it just gets bboxes for self.
"""
bboxes = []
bboxes2 = []
# get the Grouper that keeps track of x-label groups for this figure
grp = self.figure._align_xlabel_grp
# if we want to align labels from other axes:
for nn, axx in enumerate(grp.get_siblings(self.axes)):
ticks_to_draw = axx.xaxis._update_ticks(renderer)
tlb, tlb2 = axx.xaxis._get_tick_bboxes(ticks_to_draw, renderer)
bboxes.extend(tlb)
bboxes2.extend(tlb2)
return bboxes, bboxes2
def _update_label_position(self, renderer):
"""
Update the label position based on the bounding box enclosing
all the ticklabels and axis spine
"""
if not self._autolabelpos:
return
# get bounding boxes for this axis and any siblings
# that have been set by `fig.align_xlabels()`
bboxes, bboxes2 = self._get_tick_boxes_siblings(renderer=renderer)
x, y = self.label.get_position()
if self.label_position == 'bottom':
try:
spine = self.axes.spines['bottom']
spinebbox = spine.get_transform().transform_path(
spine.get_path()).get_extents()
except KeyError:
# use axes if spine doesn't exist
spinebbox = self.axes.bbox
bbox = mtransforms.Bbox.union(bboxes + [spinebbox])
bottom = bbox.y0
self.label.set_position(
(x, bottom - self.labelpad * self.figure.dpi / 72)
)
else:
try:
spine = self.axes.spines['top']
spinebbox = spine.get_transform().transform_path(
spine.get_path()).get_extents()
except KeyError:
# use axes if spine doesn't exist
spinebbox = self.axes.bbox
bbox = mtransforms.Bbox.union(bboxes2 + [spinebbox])
top = bbox.y1
self.label.set_position(
(x, top + self.labelpad * self.figure.dpi / 72)
)
def _update_offset_text_position(self, bboxes, bboxes2):
"""
Update the offset_text position based on the sequence of bounding
boxes of all the ticklabels
"""
x, y = self.offsetText.get_position()
if not len(bboxes):
bottom = self.axes.bbox.ymin
else:
bbox = mtransforms.Bbox.union(bboxes)
bottom = bbox.y0
self.offsetText.set_position(
(x, bottom - self.OFFSETTEXTPAD * self.figure.dpi / 72)
)
def get_text_heights(self, renderer):
"""
Returns the amount of space one should reserve for text
above and below the axes. Returns a tuple (above, below)
"""
bbox, bbox2 = self.get_ticklabel_extents(renderer)
# MGDTODO: Need a better way to get the pad
padPixels = self.majorTicks[0].get_pad_pixels()
above = 0.0
if bbox2.height:
above += bbox2.height + padPixels
below = 0.0
if bbox.height:
below += bbox.height + padPixels
if self.get_label_position() == 'top':
above += self.label.get_window_extent(renderer).height + padPixels
else:
below += self.label.get_window_extent(renderer).height + padPixels
return above, below
def set_ticks_position(self, position):
"""
Set the ticks position (top, bottom, both, default or none)
both sets the ticks to appear on both positions, but does not
change the tick labels. 'default' resets the tick positions to
the default: ticks on both positions, labels at bottom. 'none'
can be used if you don't want any ticks. 'none' and 'both'
affect only the ticks, not the labels.
Parameters
----------
position : {'top', 'bottom', 'both', 'default', 'none'}
"""
if position == 'top':
self.set_tick_params(which='both', top=True, labeltop=True,
bottom=False, labelbottom=False)
elif position == 'bottom':
self.set_tick_params(which='both', top=False, labeltop=False,
bottom=True, labelbottom=True)
elif position == 'both':
self.set_tick_params(which='both', top=True,
bottom=True)
elif position == 'none':
self.set_tick_params(which='both', top=False,
bottom=False)
elif position == 'default':
self.set_tick_params(which='both', top=True, labeltop=False,
bottom=True, labelbottom=True)
else:
raise ValueError("invalid position: %s" % position)
self.stale = True
def tick_top(self):
"""
Move ticks and ticklabels (if present) to the top of the axes.
"""
label = True
if 'label1On' in self._major_tick_kw:
label = (self._major_tick_kw['label1On']
or self._major_tick_kw['label2On'])
self.set_ticks_position('top')
# if labels were turned off before this was called
# leave them off
self.set_tick_params(which='both', labeltop=label)
def tick_bottom(self):
"""
Move ticks and ticklabels (if present) to the bottom of the axes.
"""
label = True
if 'label1On' in self._major_tick_kw:
label = (self._major_tick_kw['label1On']
or self._major_tick_kw['label2On'])
self.set_ticks_position('bottom')
# if labels were turned off before this was called
# leave them off
self.set_tick_params(which='both', labelbottom=label)
def get_ticks_position(self):
"""
Return the ticks position (top, bottom, default or unknown)
"""
majt = self.majorTicks[0]
mT = self.minorTicks[0]
majorTop = ((not majt.tick1On) and majt.tick2On and
(not majt.label1On) and majt.label2On)
minorTop = ((not mT.tick1On) and mT.tick2On and
(not mT.label1On) and mT.label2On)
if majorTop and minorTop:
return 'top'
MajorBottom = (majt.tick1On and (not majt.tick2On) and
majt.label1On and (not majt.label2On))
MinorBottom = (mT.tick1On and (not mT.tick2On) and
mT.label1On and (not mT.label2On))
if MajorBottom and MinorBottom:
return 'bottom'
majorDefault = (majt.tick1On and majt.tick2On and
majt.label1On and (not majt.label2On))
minorDefault = (mT.tick1On and mT.tick2On and
mT.label1On and (not mT.label2On))
if majorDefault and minorDefault:
return 'default'
return 'unknown'
def get_view_interval(self):
'return the Interval instance for this axis view limits'
return self.axes.viewLim.intervalx
def set_view_interval(self, vmin, vmax, ignore=False):
"""
If *ignore* is *False*, the order of vmin, vmax
does not matter; the original axis orientation will
be preserved. In addition, the view limits can be
expanded, but will not be reduced. This method is
for mpl internal use; for normal use, see
:meth:`~matplotlib.axes.Axes.set_xlim`.
"""
if ignore:
self.axes.viewLim.intervalx = vmin, vmax
else:
Vmin, Vmax = self.get_view_interval()
if Vmin < Vmax:
self.axes.viewLim.intervalx = (min(vmin, vmax, Vmin),
max(vmin, vmax, Vmax))
else:
self.axes.viewLim.intervalx = (max(vmin, vmax, Vmin),
min(vmin, vmax, Vmax))
def get_minpos(self):
return self.axes.dataLim.minposx
def get_data_interval(self):
'return the Interval instance for this axis data limits'
return self.axes.dataLim.intervalx
def set_data_interval(self, vmin, vmax, ignore=False):
'set the axis data limits'
if ignore:
self.axes.dataLim.intervalx = vmin, vmax
else:
Vmin, Vmax = self.get_data_interval()
self.axes.dataLim.intervalx = min(vmin, Vmin), max(vmax, Vmax)
self.stale = True
def set_default_intervals(self):
'set the default limits for the axis interval if they are not mutated'
xmin, xmax = 0., 1.
dataMutated = self.axes.dataLim.mutatedx()
viewMutated = self.axes.viewLim.mutatedx()
if not dataMutated or not viewMutated:
if self.converter is not None:
info = self.converter.axisinfo(self.units, self)
if info.default_limits is not None:
valmin, valmax = info.default_limits
xmin = self.converter.convert(valmin, self.units, self)
xmax = self.converter.convert(valmax, self.units, self)
if not dataMutated:
self.axes.dataLim.intervalx = xmin, xmax
if not viewMutated:
self.axes.viewLim.intervalx = xmin, xmax
self.stale = True
def get_tick_space(self):
ends = self.axes.transAxes.transform([[0, 0], [1, 0]])
length = ((ends[1][0] - ends[0][0]) / self.axes.figure.dpi) * 72
tick = self._get_tick(True)
# There is a heuristic here that the aspect ratio of tick text
# is no more than 3:1
size = tick.label1.get_size() * 3
if size > 0:
return int(np.floor(length / size))
else:
return 2**31 - 1
class YAxis(Axis):
__name__ = 'yaxis'
axis_name = 'y'
def contains(self, mouseevent):
"""Test whether the mouse event occurred in the y axis.
Returns *True* | *False*
"""
if callable(self._contains):
return self._contains(self, mouseevent)
x, y = mouseevent.x, mouseevent.y
try:
trans = self.axes.transAxes.inverted()
xaxes, yaxes = trans.transform_point((x, y))
except ValueError:
return False, {}
l, b = self.axes.transAxes.transform_point((0, 0))
r, t = self.axes.transAxes.transform_point((1, 1))
inaxis = 0 <= yaxes <= 1 and (
l - self.pickradius < x < l or
r < x < r + self.pickradius)
return inaxis, {}
def _get_tick(self, major):
if major:
tick_kw = self._major_tick_kw
else:
tick_kw = self._minor_tick_kw
return YTick(self.axes, 0, '', major=major, **tick_kw)
def _get_label(self):
# x in display coords (updated by _update_label_position)
# y in axes coords
label = mtext.Text(x=0, y=0.5,
# todo: get the label position
fontproperties=font_manager.FontProperties(
size=rcParams['axes.labelsize'],
weight=rcParams['axes.labelweight']),
color=rcParams['axes.labelcolor'],
verticalalignment='bottom',
horizontalalignment='center',
rotation='vertical',
rotation_mode='anchor')
label.set_transform(mtransforms.blended_transform_factory(
mtransforms.IdentityTransform(), self.axes.transAxes))
self._set_artist_props(label)
self.label_position = 'left'
return label
def _get_offset_text(self):
# x in display coords, y in axes coords (to be updated at draw time)
offsetText = mtext.Text(x=0, y=0.5,
fontproperties=font_manager.FontProperties(
size=rcParams['ytick.labelsize']
),
color=rcParams['ytick.color'],
verticalalignment='baseline',
horizontalalignment='left')
offsetText.set_transform(mtransforms.blended_transform_factory(
self.axes.transAxes, mtransforms.IdentityTransform())
)
self._set_artist_props(offsetText)
self.offset_text_position = 'left'
return offsetText
def _get_pixel_distance_along_axis(self, where, perturb):
"""
Returns the amount, in data coordinates, that a single pixel
corresponds to in the locality given by *where*, which is also given
in data coordinates, and is a y coordinate.
*perturb* is the amount to perturb the pixel. Usually +0.5 or -0.5.
Implementing this routine for an axis is optional; if present, it will
ensure that no ticks are lost due to round-off at the extreme ends of
an axis.
"""
#
# first figure out the pixel location of the "where" point. We use
# 1e-10 for the x point, so that we remain compatible with log axes.
# transformation from data coords to display coords
trans = self.axes.transData
# transformation from display coords to data coords
transinv = trans.inverted()
pix = trans.transform_point((1e-10, where))
# perturb the pixel
ptp = transinv.transform_point((pix[0], pix[1] + perturb))
dy = abs(ptp[1] - where)
return dy
def set_label_position(self, position):
"""
Set the label position (left or right)
Parameters
----------
position : {'left', 'right'}
"""
self.label.set_rotation_mode('anchor')
self.label.set_horizontalalignment('center')
if position == 'left':
self.label.set_verticalalignment('bottom')
elif position == 'right':
self.label.set_verticalalignment('top')
else:
raise ValueError("Position accepts only 'left' or 'right'")
self.label_position = position
self.stale = True
def _get_tick_boxes_siblings(self, renderer):
"""
Get the bounding boxes for this `.axis` and its siblings
as set by `.Figure.align_xlabels` or `.Figure.align_ylablels`.
By default it just gets bboxes for self.
"""
bboxes = []
bboxes2 = []
# get the Grouper that keeps track of y-label groups for this figure
grp = self.figure._align_ylabel_grp
# if we want to align labels from other axes:
for axx in grp.get_siblings(self.axes):
ticks_to_draw = axx.yaxis._update_ticks(renderer)
tlb, tlb2 = axx.yaxis._get_tick_bboxes(ticks_to_draw, renderer)
bboxes.extend(tlb)
bboxes2.extend(tlb2)
return bboxes, bboxes2
def _update_label_position(self, renderer):
"""
Update the label position based on the bounding box enclosing
all the ticklabels and axis spine
"""
if not self._autolabelpos:
return
# get bounding boxes for this axis and any siblings
# that have been set by `fig.align_ylabels()`
bboxes, bboxes2 = self._get_tick_boxes_siblings(renderer=renderer)
x, y = self.label.get_position()
if self.label_position == 'left':
try:
spine = self.axes.spines['left']
spinebbox = spine.get_transform().transform_path(
spine.get_path()).get_extents()
except KeyError:
# use axes if spine doesn't exist
spinebbox = self.axes.bbox
bbox = mtransforms.Bbox.union(bboxes + [spinebbox])
left = bbox.x0
self.label.set_position(
(left - self.labelpad * self.figure.dpi / 72, y)
)
else:
try:
spine = self.axes.spines['right']
spinebbox = spine.get_transform().transform_path(
spine.get_path()).get_extents()
except KeyError:
# use axes if spine doesn't exist
spinebbox = self.axes.bbox
bbox = mtransforms.Bbox.union(bboxes2 + [spinebbox])
right = bbox.x1
self.label.set_position(
(right + self.labelpad * self.figure.dpi / 72, y)
)
def _update_offset_text_position(self, bboxes, bboxes2):
"""
Update the offset_text position based on the sequence of bounding
boxes of all the ticklabels
"""
x, y = self.offsetText.get_position()
top = self.axes.bbox.ymax
self.offsetText.set_position(
(x, top + self.OFFSETTEXTPAD * self.figure.dpi / 72)
)
def set_offset_position(self, position):
"""
Parameters
----------
position : {'left', 'right'}
"""
x, y = self.offsetText.get_position()
if position == 'left':
x = 0
elif position == 'right':
x = 1
else:
raise ValueError("Position accepts only [ 'left' | 'right' ]")
self.offsetText.set_ha(position)
self.offsetText.set_position((x, y))
self.stale = True
def get_text_widths(self, renderer):
bbox, bbox2 = self.get_ticklabel_extents(renderer)
# MGDTODO: Need a better way to get the pad
padPixels = self.majorTicks[0].get_pad_pixels()
left = 0.0
if bbox.width:
left += bbox.width + padPixels
right = 0.0
if bbox2.width:
right += bbox2.width + padPixels
if self.get_label_position() == 'left':
left += self.label.get_window_extent(renderer).width + padPixels
else:
right += self.label.get_window_extent(renderer).width + padPixels
return left, right
def set_ticks_position(self, position):
"""
Set the ticks position (left, right, both, default or none)
'both' sets the ticks to appear on both positions, but does not
change the tick labels. 'default' resets the tick positions to
the default: ticks on both positions, labels at left. 'none'
can be used if you don't want any ticks. 'none' and 'both'
affect only the ticks, not the labels.
Parameters
----------
position : {'left', 'right', 'both', 'default', 'none'}
"""
if position == 'right':
self.set_tick_params(which='both', right=True, labelright=True,
left=False, labelleft=False)
self.set_offset_position(position)
elif position == 'left':
self.set_tick_params(which='both', right=False, labelright=False,
left=True, labelleft=True)
self.set_offset_position(position)
elif position == 'both':
self.set_tick_params(which='both', right=True,
left=True)
elif position == 'none':
self.set_tick_params(which='both', right=False,
left=False)
elif position == 'default':
self.set_tick_params(which='both', right=True, labelright=False,
left=True, labelleft=True)
else:
raise ValueError("invalid position: %s" % position)
self.stale = True
def tick_right(self):
"""
Move ticks and ticklabels (if present) to the right of the axes.
"""
label = True
if 'label1On' in self._major_tick_kw:
label = (self._major_tick_kw['label1On']
or self._major_tick_kw['label2On'])
self.set_ticks_position('right')
# if labels were turned off before this was called
# leave them off
self.set_tick_params(which='both', labelright=label)
def tick_left(self):
"""
Move ticks and ticklabels (if present) to the left of the axes.
"""
label = True
if 'label1On' in self._major_tick_kw:
label = (self._major_tick_kw['label1On']
or self._major_tick_kw['label2On'])
self.set_ticks_position('left')
# if labels were turned off before this was called
# leave them off
self.set_tick_params(which='both', labelleft=label)
def get_ticks_position(self):
"""
Return the ticks position (left, right, both or unknown)
"""
majt = self.majorTicks[0]
mT = self.minorTicks[0]
majorRight = ((not majt.tick1On) and majt.tick2On and
(not majt.label1On) and majt.label2On)
minorRight = ((not mT.tick1On) and mT.tick2On and
(not mT.label1On) and mT.label2On)
if majorRight and minorRight:
return 'right'
majorLeft = (majt.tick1On and (not majt.tick2On) and
majt.label1On and (not majt.label2On))
minorLeft = (mT.tick1On and (not mT.tick2On) and
mT.label1On and (not mT.label2On))
if majorLeft and minorLeft:
return 'left'
majorDefault = (majt.tick1On and majt.tick2On and
majt.label1On and (not majt.label2On))
minorDefault = (mT.tick1On and mT.tick2On and
mT.label1On and (not mT.label2On))
if majorDefault and minorDefault:
return 'default'
return 'unknown'
def get_view_interval(self):
'return the Interval instance for this axis view limits'
return self.axes.viewLim.intervaly
def set_view_interval(self, vmin, vmax, ignore=False):
"""
If *ignore* is *False*, the order of vmin, vmax
does not matter; the original axis orientation will
be preserved. In addition, the view limits can be
expanded, but will not be reduced. This method is
for mpl internal use; for normal use, see
:meth:`~matplotlib.axes.Axes.set_ylim`.
"""
if ignore:
self.axes.viewLim.intervaly = vmin, vmax
else:
Vmin, Vmax = self.get_view_interval()
if Vmin < Vmax:
self.axes.viewLim.intervaly = (min(vmin, vmax, Vmin),
max(vmin, vmax, Vmax))
else:
self.axes.viewLim.intervaly = (max(vmin, vmax, Vmin),
min(vmin, vmax, Vmax))
self.stale = True
def get_minpos(self):
return self.axes.dataLim.minposy
def get_data_interval(self):
'return the Interval instance for this axis data limits'
return self.axes.dataLim.intervaly
def set_data_interval(self, vmin, vmax, ignore=False):
'set the axis data limits'
if ignore:
self.axes.dataLim.intervaly = vmin, vmax
else:
Vmin, Vmax = self.get_data_interval()
self.axes.dataLim.intervaly = min(vmin, Vmin), max(vmax, Vmax)
self.stale = True
def set_default_intervals(self):
'set the default limits for the axis interval if they are not mutated'
ymin, ymax = 0., 1.
dataMutated = self.axes.dataLim.mutatedy()
viewMutated = self.axes.viewLim.mutatedy()
if not dataMutated or not viewMutated:
if self.converter is not None:
info = self.converter.axisinfo(self.units, self)
if info.default_limits is not None:
valmin, valmax = info.default_limits
ymin = self.converter.convert(valmin, self.units, self)
ymax = self.converter.convert(valmax, self.units, self)
if not dataMutated:
self.axes.dataLim.intervaly = ymin, ymax
if not viewMutated:
self.axes.viewLim.intervaly = ymin, ymax
self.stale = True
def get_tick_space(self):
ends = self.axes.transAxes.transform([[0, 0], [0, 1]])
length = ((ends[1][1] - ends[0][1]) / self.axes.figure.dpi) * 72
tick = self._get_tick(True)
# Having a spacing of at least 2 just looks good.
size = tick.label1.get_size() * 2.0
if size > 0:
return int(np.floor(length / size))
else:
return 2**31 - 1