hub/venv/lib/python3.7/site-packages/mpl_toolkits/mplot3d/axis3d.py

# axis3d.py, original mplot3d version by John Porter
# Created: 23 Sep 2005
# Parts rewritten by Reinier Heeres <reinier@heeres.eu>

import numpy as np

from matplotlib import (
    artist, cbook, lines as mlines, axis as maxis, patches as mpatches,
    rcParams)
from . import art3d, proj3d


@cbook.deprecated("3.1")
def get_flip_min_max(coord, index, mins, maxs):
    if coord[index] == mins[index]:
        return maxs[index]
    else:
        return mins[index]


def move_from_center(coord, centers, deltas, axmask=(True, True, True)):
    """
    For each coordinate where *axmask* is True, move *coord* away from
    *centers* by *deltas*.
    """
    coord = np.asarray(coord)
    return coord + axmask * np.copysign(1, coord - centers) * deltas


def tick_update_position(tick, tickxs, tickys, labelpos):
    '''Update tick line and label position and style.'''

    tick.label1.set_position(labelpos)
    tick.label2.set_position(labelpos)
    tick.tick1line.set_visible(True)
    tick.tick2line.set_visible(False)
    tick.tick1line.set_linestyle('-')
    tick.tick1line.set_marker('')
    tick.tick1line.set_data(tickxs, tickys)
    tick.gridline.set_data(0, 0)


class Axis(maxis.XAxis):
    """An Axis class for the 3D plots."""
    # These points from the unit cube make up the x, y and z-planes
    _PLANES = (
        (0, 3, 7, 4), (1, 2, 6, 5),     # yz planes
        (0, 1, 5, 4), (3, 2, 6, 7),     # xz planes
        (0, 1, 2, 3), (4, 5, 6, 7),     # xy planes
    )

    # Some properties for the axes
    _AXINFO = {
        'x': {'i': 0, 'tickdir': 1, 'juggled': (1, 0, 2),
            'color': (0.95, 0.95, 0.95, 0.5)},
        'y': {'i': 1, 'tickdir': 0, 'juggled': (0, 1, 2),
            'color': (0.90, 0.90, 0.90, 0.5)},
        'z': {'i': 2, 'tickdir': 0, 'juggled': (0, 2, 1),
            'color': (0.925, 0.925, 0.925, 0.5)},
    }

    def __init__(self, adir, v_intervalx, d_intervalx, axes, *args,
                 rotate_label=None, **kwargs):
        # adir identifies which axes this is
        self.adir = adir

        # This is a temporary member variable.
        # Do not depend on this existing in future releases!
        self._axinfo = self._AXINFO[adir].copy()
        if rcParams['_internal.classic_mode']:
            self._axinfo.update(
                {'label': {'va': 'center',
                           'ha': 'center'},
                 'tick': {'inward_factor': 0.2,
                          'outward_factor': 0.1,
                          'linewidth': rcParams['lines.linewidth']},
                 'axisline': {'linewidth': 0.75,
                              'color': (0, 0, 0, 1)},
                 'grid': {'color': (0.9, 0.9, 0.9, 1),
                          'linewidth': 1.0,
                          'linestyle': '-'},
                 })
        else:
            self._axinfo.update(
                {'label': {'va': 'center',
                           'ha': 'center'},
                 'tick': {'inward_factor': 0.2,
                          'outward_factor': 0.1,
                          'linewidth': rcParams.get(
                              adir + 'tick.major.width',
                              rcParams['xtick.major.width'])},
                 'axisline': {'linewidth': rcParams['axes.linewidth'],
                              'color': rcParams['axes.edgecolor']},
                 'grid': {'color': rcParams['grid.color'],
                          'linewidth': rcParams['grid.linewidth'],
                          'linestyle': rcParams['grid.linestyle']},
                 })

        maxis.XAxis.__init__(self, axes, *args, **kwargs)

        # data and viewing intervals for this direction
        self.d_interval = d_intervalx
        self.v_interval = v_intervalx
        self.set_rotate_label(rotate_label)

    def init3d(self):
        self.line = mlines.Line2D(
            xdata=(0, 0), ydata=(0, 0),
            linewidth=self._axinfo['axisline']['linewidth'],
            color=self._axinfo['axisline']['color'],
            antialiased=True)

        # Store dummy data in Polygon object
        self.pane = mpatches.Polygon(
            np.array([[0, 0], [0, 1], [1, 0], [0, 0]]),
            closed=False, alpha=0.8, facecolor='k', edgecolor='k')
        self.set_pane_color(self._axinfo['color'])

        self.axes._set_artist_props(self.line)
        self.axes._set_artist_props(self.pane)
        self.gridlines = art3d.Line3DCollection([])
        self.axes._set_artist_props(self.gridlines)
        self.axes._set_artist_props(self.label)
        self.axes._set_artist_props(self.offsetText)
        # Need to be able to place the label at the correct location
        self.label._transform = self.axes.transData
        self.offsetText._transform = self.axes.transData

    @cbook.deprecated("3.1")
    def get_tick_positions(self):
        majorLocs = self.major.locator()
        majorLabels = self.major.formatter.format_ticks(majorLocs)
        return majorLabels, majorLocs

    def get_major_ticks(self, numticks=None):
        ticks = maxis.XAxis.get_major_ticks(self, numticks)
        for t in ticks:
            t.tick1line.set_transform(self.axes.transData)
            t.tick2line.set_transform(self.axes.transData)
            t.gridline.set_transform(self.axes.transData)
            t.label1.set_transform(self.axes.transData)
            t.label2.set_transform(self.axes.transData)
        return ticks

    def set_pane_pos(self, xys):
        xys = np.asarray(xys)
        xys = xys[:, :2]
        self.pane.xy = xys
        self.stale = True

    def set_pane_color(self, color):
        '''Set pane color to a RGBA tuple.'''
        self._axinfo['color'] = color
        self.pane.set_edgecolor(color)
        self.pane.set_facecolor(color)
        self.pane.set_alpha(color[-1])
        self.stale = True

    def set_rotate_label(self, val):
        '''
        Whether to rotate the axis label: True, False or None.
        If set to None the label will be rotated if longer than 4 chars.
        '''
        self._rotate_label = val
        self.stale = True

    def get_rotate_label(self, text):
        if self._rotate_label is not None:
            return self._rotate_label
        else:
            return len(text) > 4

    def _get_coord_info(self, renderer):
        mins, maxs = np.array([
            self.axes.get_xbound(),
            self.axes.get_ybound(),
            self.axes.get_zbound(),
        ]).T
        centers = (maxs + mins) / 2.
        deltas = (maxs - mins) / 12.
        mins = mins - deltas / 4.
        maxs = maxs + deltas / 4.

        vals = mins[0], maxs[0], mins[1], maxs[1], mins[2], maxs[2]
        tc = self.axes.tunit_cube(vals, renderer.M)
        avgz = [tc[p1][2] + tc[p2][2] + tc[p3][2] + tc[p4][2]
                for p1, p2, p3, p4 in self._PLANES]
        highs = np.array([avgz[2*i] < avgz[2*i+1] for i in range(3)])

        return mins, maxs, centers, deltas, tc, highs

    def draw_pane(self, renderer):
        renderer.open_group('pane3d', gid=self.get_gid())

        mins, maxs, centers, deltas, tc, highs = self._get_coord_info(renderer)

        info = self._axinfo
        index = info['i']
        if not highs[index]:
            plane = self._PLANES[2 * index]
        else:
            plane = self._PLANES[2 * index + 1]
        xys = [tc[p] for p in plane]
        self.set_pane_pos(xys)
        self.pane.draw(renderer)

        renderer.close_group('pane3d')

    @artist.allow_rasterization
    def draw(self, renderer):
        self.label._transform = self.axes.transData
        renderer.open_group('axis3d', gid=self.get_gid())

        ticks = self._update_ticks()

        info = self._axinfo
        index = info['i']

        mins, maxs, centers, deltas, tc, highs = self._get_coord_info(renderer)

        # Determine grid lines
        minmax = np.where(highs, maxs, mins)
        maxmin = np.where(highs, mins, maxs)

        # Draw main axis line
        juggled = info['juggled']
        edgep1 = minmax.copy()
        edgep1[juggled[0]] = maxmin[juggled[0]]

        edgep2 = edgep1.copy()
        edgep2[juggled[1]] = maxmin[juggled[1]]
        pep = np.asarray(
            proj3d.proj_trans_points([edgep1, edgep2], renderer.M))
        centpt = proj3d.proj_transform(*centers, renderer.M)
        self.line.set_data(pep[0], pep[1])
        self.line.draw(renderer)

        # Grid points where the planes meet
        xyz0 = np.tile(minmax, (len(ticks), 1))
        xyz0[:, index] = [tick.get_loc() for tick in ticks]

        # Draw labels
        # The transAxes transform is used because the Text object
        # rotates the text relative to the display coordinate system.
        # Therefore, if we want the labels to remain parallel to the
        # axis regardless of the aspect ratio, we need to convert the
        # edge points of the plane to display coordinates and calculate
        # an angle from that.
        # TODO: Maybe Text objects should handle this themselves?
        dx, dy = (self.axes.transAxes.transform([pep[0:2, 1]]) -
                  self.axes.transAxes.transform([pep[0:2, 0]]))[0]

        lxyz = 0.5 * (edgep1 + edgep2)

        # A rough estimate; points are ambiguous since 3D plots rotate
        ax_scale = self.axes.bbox.size / self.figure.bbox.size
        ax_inches = np.multiply(ax_scale, self.figure.get_size_inches())
        ax_points_estimate = sum(72. * ax_inches)
        deltas_per_point = 48 / ax_points_estimate
        default_offset = 21.
        labeldeltas = (
            (self.labelpad + default_offset) * deltas_per_point * deltas)
        axmask = [True, True, True]
        axmask[index] = False
        lxyz = move_from_center(lxyz, centers, labeldeltas, axmask)
        tlx, tly, tlz = proj3d.proj_transform(*lxyz, renderer.M)
        self.label.set_position((tlx, tly))
        if self.get_rotate_label(self.label.get_text()):
            angle = art3d._norm_text_angle(np.rad2deg(np.arctan2(dy, dx)))
            self.label.set_rotation(angle)
        self.label.set_va(info['label']['va'])
        self.label.set_ha(info['label']['ha'])
        self.label.draw(renderer)

        # Draw Offset text

        # Which of the two edge points do we want to
        # use for locating the offset text?
        if juggled[2] == 2:
            outeredgep = edgep1
            outerindex = 0
        else:
            outeredgep = edgep2
            outerindex = 1

        pos = move_from_center(outeredgep, centers, labeldeltas, axmask)
        olx, oly, olz = proj3d.proj_transform(*pos, renderer.M)
        self.offsetText.set_text(self.major.formatter.get_offset())
        self.offsetText.set_position((olx, oly))
        angle = art3d._norm_text_angle(np.rad2deg(np.arctan2(dy, dx)))
        self.offsetText.set_rotation(angle)
        # Must set rotation mode to "anchor" so that
        # the alignment point is used as the "fulcrum" for rotation.
        self.offsetText.set_rotation_mode('anchor')

        #----------------------------------------------------------------------
        # Note: the following statement for determining the proper alignment of
        # the offset text. This was determined entirely by trial-and-error
        # and should not be in any way considered as "the way".  There are
        # still some edge cases where alignment is not quite right, but this
        # seems to be more of a geometry issue (in other words, I might be
        # using the wrong reference points).
        #
        # (TT, FF, TF, FT) are the shorthand for the tuple of
        #   (centpt[info['tickdir']] <= pep[info['tickdir'], outerindex],
        #    centpt[index] <= pep[index, outerindex])
        #
        # Three-letters (e.g., TFT, FTT) are short-hand for the array of bools
        # from the variable 'highs'.
        # ---------------------------------------------------------------------
        if centpt[info['tickdir']] > pep[info['tickdir'], outerindex]:
            # if FT and if highs has an even number of Trues
            if (centpt[index] <= pep[index, outerindex]
                    and np.count_nonzero(highs) % 2 == 0):
                # Usually, this means align right, except for the FTT case,
                # in which offset for axis 1 and 2 are aligned left.
                if highs.tolist() == [False, True, True] and index in (1, 2):
                    align = 'left'
                else:
                    align = 'right'
            else:
                # The FF case
                align = 'left'
        else:
            # if TF and if highs has an even number of Trues
            if (centpt[index] > pep[index, outerindex]
                    and np.count_nonzero(highs) % 2 == 0):
                # Usually mean align left, except if it is axis 2
                if index == 2:
                    align = 'right'
                else:
                    align = 'left'
            else:
                # The TT case
                align = 'right'

        self.offsetText.set_va('center')
        self.offsetText.set_ha(align)
        self.offsetText.draw(renderer)

        if self.axes._draw_grid and len(ticks):
            # Grid lines go from the end of one plane through the plane
            # intersection (at xyz0) to the end of the other plane.  The first
            # point (0) differs along dimension index-2 and the last (2) along
            # dimension index-1.
            lines = np.stack([xyz0, xyz0, xyz0], axis=1)
            lines[:, 0, index - 2] = maxmin[index - 2]
            lines[:, 2, index - 1] = maxmin[index - 1]
            self.gridlines.set_segments(lines)
            self.gridlines.set_color(info['grid']['color'])
            self.gridlines.set_linewidth(info['grid']['linewidth'])
            self.gridlines.set_linestyle(info['grid']['linestyle'])
            self.gridlines.draw(renderer, project=True)

        # Draw ticks
        tickdir = info['tickdir']
        tickdelta = deltas[tickdir]
        if highs[tickdir]:
            ticksign = 1
        else:
            ticksign = -1

        for tick in ticks:
            # Get tick line positions
            pos = edgep1.copy()
            pos[index] = tick.get_loc()
            pos[tickdir] = (
                edgep1[tickdir]
                + info['tick']['outward_factor'] * ticksign * tickdelta)
            x1, y1, z1 = proj3d.proj_transform(*pos, renderer.M)
            pos[tickdir] = (
                edgep1[tickdir]
                - info['tick']['inward_factor'] * ticksign * tickdelta)
            x2, y2, z2 = proj3d.proj_transform(*pos, renderer.M)

            # Get position of label
            default_offset = 8.  # A rough estimate
            labeldeltas = (
                (tick.get_pad() + default_offset) * deltas_per_point * deltas)

            axmask = [True, True, True]
            axmask[index] = False
            pos[tickdir] = edgep1[tickdir]
            pos = move_from_center(pos, centers, labeldeltas, axmask)
            lx, ly, lz = proj3d.proj_transform(*pos, renderer.M)

            tick_update_position(tick, (x1, x2), (y1, y2), (lx, ly))
            tick.tick1line.set_linewidth(info['tick']['linewidth'])
            tick.draw(renderer)

        renderer.close_group('axis3d')
        self.stale = False

    # TODO: Get this to work properly when mplot3d supports
    #       the transforms framework.
    def get_tightbbox(self, renderer):
        # Currently returns None so that Axis.get_tightbbox
        # doesn't return junk info.
        return None

    @property
    def d_interval(self):
        return self.get_data_interval()

    @d_interval.setter
    def d_interval(self, minmax):
        return self.set_data_interval(*minmax)

    @property
    def v_interval(self):
        return self.get_view_interval()

    @v_interval.setter
    def v_interval(self, minmax):
        return self.set_view_interval(*minmax)


# Use classes to look at different data limits


class XAxis(Axis):
    get_view_interval, set_view_interval = maxis._make_getset_interval(
        "view", "xy_viewLim", "intervalx")
    get_data_interval, set_data_interval = maxis._make_getset_interval(
        "data", "xy_dataLim", "intervalx")


class YAxis(Axis):
    get_view_interval, set_view_interval = maxis._make_getset_interval(
        "view", "xy_viewLim", "intervaly")
    get_data_interval, set_data_interval = maxis._make_getset_interval(
        "data", "xy_dataLim", "intervaly")


class ZAxis(Axis):
    get_view_interval, set_view_interval = maxis._make_getset_interval(
        "view", "zz_viewLim", "intervalx")
    get_data_interval, set_data_interval = maxis._make_getset_interval(
        "data", "zz_dataLim", "intervalx")
Add virtual environment to the git repository, this isn't 100% right but it's practical at this development point 2020-06-16 10:34:17 -04:00			`# axis3d.py, original mplot3d version by John Porter`
			`# Created: 23 Sep 2005`
			`# Parts rewritten by Reinier Heeres <reinier@heeres.eu>`

			`import numpy as np`

			`from matplotlib import (`
			`artist, cbook, lines as mlines, axis as maxis, patches as mpatches,`
			`rcParams)`
			`from . import art3d, proj3d`


			`@cbook.deprecated("3.1")`
			`def get_flip_min_max(coord, index, mins, maxs):`
			`if coord[index] == mins[index]:`
			`return maxs[index]`
			`else:`
			`return mins[index]`


			`def move_from_center(coord, centers, deltas, axmask=(True, True, True)):`
			`"""`
			`For each coordinate where axmask is True, move coord away from`
			`centers by deltas.`
			`"""`
			`coord = np.asarray(coord)`
			`return coord + axmask * np.copysign(1, coord - centers) * deltas`


			`def tick_update_position(tick, tickxs, tickys, labelpos):`
			`'''Update tick line and label position and style.'''`

			`tick.label1.set_position(labelpos)`
			`tick.label2.set_position(labelpos)`
			`tick.tick1line.set_visible(True)`
			`tick.tick2line.set_visible(False)`
			`tick.tick1line.set_linestyle('-')`
			`tick.tick1line.set_marker('')`
			`tick.tick1line.set_data(tickxs, tickys)`
			`tick.gridline.set_data(0, 0)`


			`class Axis(maxis.XAxis):`
			`"""An Axis class for the 3D plots."""`
			`# These points from the unit cube make up the x, y and z-planes`
			`_PLANES = (`
			`(0, 3, 7, 4), (1, 2, 6, 5), # yz planes`
			`(0, 1, 5, 4), (3, 2, 6, 7), # xz planes`
			`(0, 1, 2, 3), (4, 5, 6, 7), # xy planes`
			`)`

			`# Some properties for the axes`
			`_AXINFO = {`
			`'x': {'i': 0, 'tickdir': 1, 'juggled': (1, 0, 2),`
			`'color': (0.95, 0.95, 0.95, 0.5)},`
			`'y': {'i': 1, 'tickdir': 0, 'juggled': (0, 1, 2),`
			`'color': (0.90, 0.90, 0.90, 0.5)},`
			`'z': {'i': 2, 'tickdir': 0, 'juggled': (0, 2, 1),`
			`'color': (0.925, 0.925, 0.925, 0.5)},`
			`}`

			`def __init__(self, adir, v_intervalx, d_intervalx, axes, *args,`
			`rotate_label=None, **kwargs):`
			`# adir identifies which axes this is`
			`self.adir = adir`

			`# This is a temporary member variable.`
			`# Do not depend on this existing in future releases!`
			`self._axinfo = self._AXINFO[adir].copy()`
			`if rcParams['_internal.classic_mode']:`
			`self._axinfo.update(`
			`{'label': {'va': 'center',`
			`'ha': 'center'},`
			`'tick': {'inward_factor': 0.2,`
			`'outward_factor': 0.1,`
			`'linewidth': rcParams['lines.linewidth']},`
			`'axisline': {'linewidth': 0.75,`
			`'color': (0, 0, 0, 1)},`
			`'grid': {'color': (0.9, 0.9, 0.9, 1),`
			`'linewidth': 1.0,`
			`'linestyle': '-'},`
			`})`
			`else:`
			`self._axinfo.update(`
			`{'label': {'va': 'center',`
			`'ha': 'center'},`
			`'tick': {'inward_factor': 0.2,`
			`'outward_factor': 0.1,`
			`'linewidth': rcParams.get(`
			`adir + 'tick.major.width',`
			`rcParams['xtick.major.width'])},`
			`'axisline': {'linewidth': rcParams['axes.linewidth'],`
			`'color': rcParams['axes.edgecolor']},`
			`'grid': {'color': rcParams['grid.color'],`
			`'linewidth': rcParams['grid.linewidth'],`
			`'linestyle': rcParams['grid.linestyle']},`
			`})`

			`maxis.XAxis.__init__(self, axes, args, *kwargs)`

			`# data and viewing intervals for this direction`
			`self.d_interval = d_intervalx`
			`self.v_interval = v_intervalx`
			`self.set_rotate_label(rotate_label)`

			`def init3d(self):`
			`self.line = mlines.Line2D(`
			`xdata=(0, 0), ydata=(0, 0),`
			`linewidth=self._axinfo['axisline']['linewidth'],`
			`color=self._axinfo['axisline']['color'],`
			`antialiased=True)`

			`# Store dummy data in Polygon object`
			`self.pane = mpatches.Polygon(`
			`np.array([[0, 0], [0, 1], [1, 0], [0, 0]]),`
			`closed=False, alpha=0.8, facecolor='k', edgecolor='k')`
			`self.set_pane_color(self._axinfo['color'])`

			`self.axes._set_artist_props(self.line)`
			`self.axes._set_artist_props(self.pane)`
			`self.gridlines = art3d.Line3DCollection([])`
			`self.axes._set_artist_props(self.gridlines)`
			`self.axes._set_artist_props(self.label)`
			`self.axes._set_artist_props(self.offsetText)`
			`# Need to be able to place the label at the correct location`
			`self.label._transform = self.axes.transData`
			`self.offsetText._transform = self.axes.transData`

			`@cbook.deprecated("3.1")`
			`def get_tick_positions(self):`
			`majorLocs = self.major.locator()`
			`majorLabels = self.major.formatter.format_ticks(majorLocs)`
			`return majorLabels, majorLocs`

			`def get_major_ticks(self, numticks=None):`
			`ticks = maxis.XAxis.get_major_ticks(self, numticks)`
			`for t in ticks:`
			`t.tick1line.set_transform(self.axes.transData)`
			`t.tick2line.set_transform(self.axes.transData)`
			`t.gridline.set_transform(self.axes.transData)`
			`t.label1.set_transform(self.axes.transData)`
			`t.label2.set_transform(self.axes.transData)`
			`return ticks`

			`def set_pane_pos(self, xys):`
			`xys = np.asarray(xys)`
			`xys = xys[:, :2]`
			`self.pane.xy = xys`
			`self.stale = True`

			`def set_pane_color(self, color):`
			`'''Set pane color to a RGBA tuple.'''`
			`self._axinfo['color'] = color`
			`self.pane.set_edgecolor(color)`
			`self.pane.set_facecolor(color)`
			`self.pane.set_alpha(color[-1])`
			`self.stale = True`

			`def set_rotate_label(self, val):`
			`'''`
			`Whether to rotate the axis label: True, False or None.`
			`If set to None the label will be rotated if longer than 4 chars.`
			`'''`
			`self._rotate_label = val`
			`self.stale = True`

			`def get_rotate_label(self, text):`
			`if self._rotate_label is not None:`
			`return self._rotate_label`
			`else:`
			`return len(text) > 4`

			`def _get_coord_info(self, renderer):`
			`mins, maxs = np.array([`
			`self.axes.get_xbound(),`
			`self.axes.get_ybound(),`
			`self.axes.get_zbound(),`
			`]).T`
			`centers = (maxs + mins) / 2.`
			`deltas = (maxs - mins) / 12.`
			`mins = mins - deltas / 4.`
			`maxs = maxs + deltas / 4.`

			`vals = mins[0], maxs[0], mins[1], maxs[1], mins[2], maxs[2]`
			`tc = self.axes.tunit_cube(vals, renderer.M)`
			`avgz = [tc[p1][2] + tc[p2][2] + tc[p3][2] + tc[p4][2]`
			`for p1, p2, p3, p4 in self._PLANES]`
			`highs = np.array([avgz[2i] < avgz[2i+1] for i in range(3)])`

			`return mins, maxs, centers, deltas, tc, highs`

			`def draw_pane(self, renderer):`
			`renderer.open_group('pane3d', gid=self.get_gid())`

			`mins, maxs, centers, deltas, tc, highs = self._get_coord_info(renderer)`

			`info = self._axinfo`
			`index = info['i']`
			`if not highs[index]:`
			`plane = self._PLANES[2 * index]`
			`else:`
			`plane = self._PLANES[2 * index + 1]`
			`xys = [tc[p] for p in plane]`
			`self.set_pane_pos(xys)`
			`self.pane.draw(renderer)`

			`renderer.close_group('pane3d')`

			`@artist.allow_rasterization`
			`def draw(self, renderer):`
			`self.label._transform = self.axes.transData`
			`renderer.open_group('axis3d', gid=self.get_gid())`

			`ticks = self._update_ticks()`

			`info = self._axinfo`
			`index = info['i']`

			`mins, maxs, centers, deltas, tc, highs = self._get_coord_info(renderer)`

			`# Determine grid lines`
			`minmax = np.where(highs, maxs, mins)`
			`maxmin = np.where(highs, mins, maxs)`

			`# Draw main axis line`
			`juggled = info['juggled']`
			`edgep1 = minmax.copy()`
			`edgep1[juggled[0]] = maxmin[juggled[0]]`

			`edgep2 = edgep1.copy()`
			`edgep2[juggled[1]] = maxmin[juggled[1]]`
			`pep = np.asarray(`
			`proj3d.proj_trans_points([edgep1, edgep2], renderer.M))`
			`centpt = proj3d.proj_transform(*centers, renderer.M)`
			`self.line.set_data(pep[0], pep[1])`
			`self.line.draw(renderer)`

			`# Grid points where the planes meet`
			`xyz0 = np.tile(minmax, (len(ticks), 1))`
			`xyz0[:, index] = [tick.get_loc() for tick in ticks]`

			`# Draw labels`
			`# The transAxes transform is used because the Text object`
			`# rotates the text relative to the display coordinate system.`
			`# Therefore, if we want the labels to remain parallel to the`
			`# axis regardless of the aspect ratio, we need to convert the`
			`# edge points of the plane to display coordinates and calculate`
			`# an angle from that.`
			`# TODO: Maybe Text objects should handle this themselves?`
			`dx, dy = (self.axes.transAxes.transform([pep[0:2, 1]]) -`
			`self.axes.transAxes.transform([pep[0:2, 0]]))[0]`

			`lxyz = 0.5 * (edgep1 + edgep2)`

			`# A rough estimate; points are ambiguous since 3D plots rotate`
			`ax_scale = self.axes.bbox.size / self.figure.bbox.size`
			`ax_inches = np.multiply(ax_scale, self.figure.get_size_inches())`
			`ax_points_estimate = sum(72. * ax_inches)`
			`deltas_per_point = 48 / ax_points_estimate`
			`default_offset = 21.`
			`labeldeltas = (`
			`(self.labelpad + default_offset) * deltas_per_point * deltas)`
			`axmask = [True, True, True]`
			`axmask[index] = False`
			`lxyz = move_from_center(lxyz, centers, labeldeltas, axmask)`
			`tlx, tly, tlz = proj3d.proj_transform(*lxyz, renderer.M)`
			`self.label.set_position((tlx, tly))`
			`if self.get_rotate_label(self.label.get_text()):`
			`angle = art3d._norm_text_angle(np.rad2deg(np.arctan2(dy, dx)))`
			`self.label.set_rotation(angle)`
			`self.label.set_va(info['label']['va'])`
			`self.label.set_ha(info['label']['ha'])`
			`self.label.draw(renderer)`

			`# Draw Offset text`

			`# Which of the two edge points do we want to`
			`# use for locating the offset text?`
			`if juggled[2] == 2:`
			`outeredgep = edgep1`
			`outerindex = 0`
			`else:`
			`outeredgep = edgep2`
			`outerindex = 1`

			`pos = move_from_center(outeredgep, centers, labeldeltas, axmask)`
			`olx, oly, olz = proj3d.proj_transform(*pos, renderer.M)`
			`self.offsetText.set_text(self.major.formatter.get_offset())`
			`self.offsetText.set_position((olx, oly))`
			`angle = art3d._norm_text_angle(np.rad2deg(np.arctan2(dy, dx)))`
			`self.offsetText.set_rotation(angle)`
			`# Must set rotation mode to "anchor" so that`
			`# the alignment point is used as the "fulcrum" for rotation.`
			`self.offsetText.set_rotation_mode('anchor')`

			`#----------------------------------------------------------------------`
			`# Note: the following statement for determining the proper alignment of`
			`# the offset text. This was determined entirely by trial-and-error`
			`# and should not be in any way considered as "the way". There are`
			`# still some edge cases where alignment is not quite right, but this`
			`# seems to be more of a geometry issue (in other words, I might be`
			`# using the wrong reference points).`
			`#`
			`# (TT, FF, TF, FT) are the shorthand for the tuple of`
			`# (centpt[info['tickdir']] <= pep[info['tickdir'], outerindex],`
			`# centpt[index] <= pep[index, outerindex])`
			`#`
			`# Three-letters (e.g., TFT, FTT) are short-hand for the array of bools`
			`# from the variable 'highs'.`
			`# ---------------------------------------------------------------------`
			`if centpt[info['tickdir']] > pep[info['tickdir'], outerindex]:`
			`# if FT and if highs has an even number of Trues`
			`if (centpt[index] <= pep[index, outerindex]`
			`and np.count_nonzero(highs) % 2 == 0):`
			`# Usually, this means align right, except for the FTT case,`
			`# in which offset for axis 1 and 2 are aligned left.`
			`if highs.tolist() == [False, True, True] and index in (1, 2):`
			`align = 'left'`
			`else:`
			`align = 'right'`
			`else:`
			`# The FF case`
			`align = 'left'`
			`else:`
			`# if TF and if highs has an even number of Trues`
			`if (centpt[index] > pep[index, outerindex]`
			`and np.count_nonzero(highs) % 2 == 0):`
			`# Usually mean align left, except if it is axis 2`
			`if index == 2:`
			`align = 'right'`
			`else:`
			`align = 'left'`
			`else:`
			`# The TT case`
			`align = 'right'`

			`self.offsetText.set_va('center')`
			`self.offsetText.set_ha(align)`
			`self.offsetText.draw(renderer)`

			`if self.axes._draw_grid and len(ticks):`
			`# Grid lines go from the end of one plane through the plane`
			`# intersection (at xyz0) to the end of the other plane. The first`
			`# point (0) differs along dimension index-2 and the last (2) along`
			`# dimension index-1.`
			`lines = np.stack([xyz0, xyz0, xyz0], axis=1)`
			`lines[:, 0, index - 2] = maxmin[index - 2]`
			`lines[:, 2, index - 1] = maxmin[index - 1]`
			`self.gridlines.set_segments(lines)`
			`self.gridlines.set_color(info['grid']['color'])`
			`self.gridlines.set_linewidth(info['grid']['linewidth'])`
			`self.gridlines.set_linestyle(info['grid']['linestyle'])`
			`self.gridlines.draw(renderer, project=True)`

			`# Draw ticks`
			`tickdir = info['tickdir']`
			`tickdelta = deltas[tickdir]`
			`if highs[tickdir]:`
			`ticksign = 1`
			`else:`
			`ticksign = -1`

			`for tick in ticks:`
			`# Get tick line positions`
			`pos = edgep1.copy()`
			`pos[index] = tick.get_loc()`
			`pos[tickdir] = (`
			`edgep1[tickdir]`
			`+ info['tick']['outward_factor'] * ticksign * tickdelta)`
			`x1, y1, z1 = proj3d.proj_transform(*pos, renderer.M)`
			`pos[tickdir] = (`
			`edgep1[tickdir]`
			`- info['tick']['inward_factor'] * ticksign * tickdelta)`
			`x2, y2, z2 = proj3d.proj_transform(*pos, renderer.M)`

			`# Get position of label`
			`default_offset = 8. # A rough estimate`
			`labeldeltas = (`
			`(tick.get_pad() + default_offset) * deltas_per_point * deltas)`

			`axmask = [True, True, True]`
			`axmask[index] = False`
			`pos[tickdir] = edgep1[tickdir]`
			`pos = move_from_center(pos, centers, labeldeltas, axmask)`
			`lx, ly, lz = proj3d.proj_transform(*pos, renderer.M)`

			`tick_update_position(tick, (x1, x2), (y1, y2), (lx, ly))`
			`tick.tick1line.set_linewidth(info['tick']['linewidth'])`
			`tick.draw(renderer)`

			`renderer.close_group('axis3d')`
			`self.stale = False`

			`# TODO: Get this to work properly when mplot3d supports`
			`# the transforms framework.`
			`def get_tightbbox(self, renderer):`
			`# Currently returns None so that Axis.get_tightbbox`
			`# doesn't return junk info.`
			`return None`

			`@property`
			`def d_interval(self):`
			`return self.get_data_interval()`

			`@d_interval.setter`
			`def d_interval(self, minmax):`
			`return self.set_data_interval(*minmax)`

			`@property`
			`def v_interval(self):`
			`return self.get_view_interval()`

			`@v_interval.setter`
			`def v_interval(self, minmax):`
			`return self.set_view_interval(*minmax)`


			`# Use classes to look at different data limits`


			`class XAxis(Axis):`
			`get_view_interval, set_view_interval = maxis._make_getset_interval(`
			`"view", "xy_viewLim", "intervalx")`
			`get_data_interval, set_data_interval = maxis._make_getset_interval(`
			`"data", "xy_dataLim", "intervalx")`


			`class YAxis(Axis):`
			`get_view_interval, set_view_interval = maxis._make_getset_interval(`
			`"view", "xy_viewLim", "intervaly")`
			`get_data_interval, set_data_interval = maxis._make_getset_interval(`
			`"data", "xy_dataLim", "intervaly")`


			`class ZAxis(Axis):`
			`get_view_interval, set_view_interval = maxis._make_getset_interval(`
			`"view", "zz_viewLim", "intervalx")`
			`get_data_interval, set_data_interval = maxis._make_getset_interval(`
			`"data", "zz_dataLim", "intervalx")`