eaiaiaiaoi/venv/lib/python2.7/site-packages/scipy/spatial/_plotutils.py

from __future__ import division, print_function, absolute_import

import numpy as np
from scipy._lib.decorator import decorator as _decorator

__all__ = ['delaunay_plot_2d', 'convex_hull_plot_2d', 'voronoi_plot_2d']


@_decorator
def _held_figure(func, obj, ax=None, **kw):
    import matplotlib.pyplot as plt

    if ax is None:
        fig = plt.figure()
        ax = fig.gca()
        return func(obj, ax=ax, **kw)

    # As of matplotlib 2.0, the "hold" mechanism is deprecated.
    # When matplotlib 1.x is no longer supported, this check can be removed.
    was_held = getattr(ax, 'ishold', lambda: True)()
    if was_held:
        return func(obj, ax=ax, **kw)
    try:
        ax.hold(True)
        return func(obj, ax=ax, **kw)
    finally:
        ax.hold(was_held)


def _adjust_bounds(ax, points):
    margin = 0.1 * points.ptp(axis=0)
    xy_min = points.min(axis=0) - margin
    xy_max = points.max(axis=0) + margin
    ax.set_xlim(xy_min[0], xy_max[0])
    ax.set_ylim(xy_min[1], xy_max[1])


@_held_figure
def delaunay_plot_2d(tri, ax=None):
    """
    Plot the given Delaunay triangulation in 2-D

    Parameters
    ----------
    tri : scipy.spatial.Delaunay instance
        Triangulation to plot
    ax : matplotlib.axes.Axes instance, optional
        Axes to plot on

    Returns
    -------
    fig : matplotlib.figure.Figure instance
        Figure for the plot

    See Also
    --------
    Delaunay
    matplotlib.pyplot.triplot

    Notes
    -----
    Requires Matplotlib.

    Examples
    --------

    >>> import matplotlib.pyplot as plt
    >>> from scipy.spatial import Delaunay, delaunay_plot_2d

    The Delaunay triangulation of a set of random points:

    >>> points = np.random.rand(30, 2)
    >>> tri = Delaunay(points)

    Plot it:

    >>> _ = delaunay_plot_2d(tri)
    >>> plt.show()

    """
    if tri.points.shape[1] != 2:
        raise ValueError("Delaunay triangulation is not 2-D")

    x, y = tri.points.T
    ax.plot(x, y, 'o')
    ax.triplot(x, y, tri.simplices.copy())

    _adjust_bounds(ax, tri.points)

    return ax.figure


@_held_figure
def convex_hull_plot_2d(hull, ax=None):
    """
    Plot the given convex hull diagram in 2-D

    Parameters
    ----------
    hull : scipy.spatial.ConvexHull instance
        Convex hull to plot
    ax : matplotlib.axes.Axes instance, optional
        Axes to plot on

    Returns
    -------
    fig : matplotlib.figure.Figure instance
        Figure for the plot

    See Also
    --------
    ConvexHull

    Notes
    -----
    Requires Matplotlib.


    Examples
    --------

    >>> import matplotlib.pyplot as plt
    >>> from scipy.spatial import ConvexHull, convex_hull_plot_2d

    The convex hull of a random set of points:

    >>> points = np.random.rand(30, 2)
    >>> hull = ConvexHull(points)

    Plot it:

    >>> _ = convex_hull_plot_2d(hull)
    >>> plt.show()

    """
    from matplotlib.collections import LineCollection

    if hull.points.shape[1] != 2:
        raise ValueError("Convex hull is not 2-D")

    ax.plot(hull.points[:,0], hull.points[:,1], 'o')
    line_segments = [hull.points[simplex] for simplex in hull.simplices]
    ax.add_collection(LineCollection(line_segments,
                                     colors='k',
                                     linestyle='solid'))
    _adjust_bounds(ax, hull.points)

    return ax.figure


@_held_figure
def voronoi_plot_2d(vor, ax=None, **kw):
    """
    Plot the given Voronoi diagram in 2-D

    Parameters
    ----------
    vor : scipy.spatial.Voronoi instance
        Diagram to plot
    ax : matplotlib.axes.Axes instance, optional
        Axes to plot on
    show_points: bool, optional
        Add the Voronoi points to the plot.
    show_vertices : bool, optional
        Add the Voronoi vertices to the plot.
    line_colors : string, optional
        Specifies the line color for polygon boundaries
    line_width : float, optional
        Specifies the line width for polygon boundaries
    line_alpha: float, optional
        Specifies the line alpha for polygon boundaries
    point_size: float, optional
        Specifies the size of points


    Returns
    -------
    fig : matplotlib.figure.Figure instance
        Figure for the plot

    See Also
    --------
    Voronoi

    Notes
    -----
    Requires Matplotlib.

    Examples
    --------
    Set of point:

    >>> import matplotlib.pyplot as plt
    >>> points = np.random.rand(10,2) #random

    Voronoi diagram of the points:

    >>> from scipy.spatial import Voronoi, voronoi_plot_2d
    >>> vor = Voronoi(points)

    using `voronoi_plot_2d` for visualisation:

    >>> fig = voronoi_plot_2d(vor)

    using `voronoi_plot_2d` for visualisation with enhancements:

    >>> fig = voronoi_plot_2d(vor, show_vertices=False, line_colors='orange',
    ...                 line_width=2, line_alpha=0.6, point_size=2)
    >>> plt.show()

    """
    from matplotlib.collections import LineCollection

    if vor.points.shape[1] != 2:
        raise ValueError("Voronoi diagram is not 2-D")

    if kw.get('show_points', True):
        point_size = kw.get('point_size', None)
        ax.plot(vor.points[:,0], vor.points[:,1], '.', markersize=point_size)
    if kw.get('show_vertices', True):
        ax.plot(vor.vertices[:,0], vor.vertices[:,1], 'o')

    line_colors = kw.get('line_colors', 'k')
    line_width = kw.get('line_width', 1.0)
    line_alpha = kw.get('line_alpha', 1.0)

    center = vor.points.mean(axis=0)
    ptp_bound = vor.points.ptp(axis=0)

    finite_segments = []
    infinite_segments = []
    for pointidx, simplex in zip(vor.ridge_points, vor.ridge_vertices):
        simplex = np.asarray(simplex)
        if np.all(simplex >= 0):
            finite_segments.append(vor.vertices[simplex])
        else:
            i = simplex[simplex >= 0][0]  # finite end Voronoi vertex

            t = vor.points[pointidx[1]] - vor.points[pointidx[0]]  # tangent
            t /= np.linalg.norm(t)
            n = np.array([-t[1], t[0]])  # normal

            midpoint = vor.points[pointidx].mean(axis=0)
            direction = np.sign(np.dot(midpoint - center, n)) * n
            far_point = vor.vertices[i] + direction * ptp_bound.max()

            infinite_segments.append([vor.vertices[i], far_point])

    ax.add_collection(LineCollection(finite_segments,
                                     colors=line_colors,
                                     lw=line_width,
                                     alpha=line_alpha,
                                     linestyle='solid'))
    ax.add_collection(LineCollection(infinite_segments,
                                     colors=line_colors,
                                     lw=line_width,
                                     alpha=line_alpha,
                                     linestyle='dashed'))

    _adjust_bounds(ax, vor.points)

    return ax.figure
add in project 6 years ago			`from __future__ import division, print_function, absolute_import`

			`import numpy as np`
			`from scipy._lib.decorator import decorator as _decorator`

			`__all__ = ['delaunay_plot_2d', 'convex_hull_plot_2d', 'voronoi_plot_2d']`


			`@_decorator`
			`def _held_figure(func, obj, ax=None, **kw):`
			`import matplotlib.pyplot as plt`

			`if ax is None:`
			`fig = plt.figure()`
			`ax = fig.gca()`
			`return func(obj, ax=ax, **kw)`

			`# As of matplotlib 2.0, the "hold" mechanism is deprecated.`
			`# When matplotlib 1.x is no longer supported, this check can be removed.`
			`was_held = getattr(ax, 'ishold', lambda: True)()`
			`if was_held:`
			`return func(obj, ax=ax, **kw)`
			`try:`
			`ax.hold(True)`
			`return func(obj, ax=ax, **kw)`
			`finally:`
			`ax.hold(was_held)`


			`def _adjust_bounds(ax, points):`
			`margin = 0.1 * points.ptp(axis=0)`
			`xy_min = points.min(axis=0) - margin`
			`xy_max = points.max(axis=0) + margin`
			`ax.set_xlim(xy_min[0], xy_max[0])`
			`ax.set_ylim(xy_min[1], xy_max[1])`


			`@_held_figure`
			`def delaunay_plot_2d(tri, ax=None):`
			`"""`
			`Plot the given Delaunay triangulation in 2-D`

			`Parameters`
			`----------`
			`tri : scipy.spatial.Delaunay instance`
			`Triangulation to plot`
			`ax : matplotlib.axes.Axes instance, optional`
			`Axes to plot on`

			`Returns`
			`-------`
			`fig : matplotlib.figure.Figure instance`
			`Figure for the plot`

			`See Also`
			`--------`
			`Delaunay`
			`matplotlib.pyplot.triplot`

			`Notes`
			`-----`
			`Requires Matplotlib.`

			`Examples`
			`--------`

			`>>> import matplotlib.pyplot as plt`
			`>>> from scipy.spatial import Delaunay, delaunay_plot_2d`

			`The Delaunay triangulation of a set of random points:`

			`>>> points = np.random.rand(30, 2)`
			`>>> tri = Delaunay(points)`

			`Plot it:`

			`>>> _ = delaunay_plot_2d(tri)`
			`>>> plt.show()`

			`"""`
			`if tri.points.shape[1] != 2:`
			`raise ValueError("Delaunay triangulation is not 2-D")`

			`x, y = tri.points.T`
			`ax.plot(x, y, 'o')`
			`ax.triplot(x, y, tri.simplices.copy())`

			`_adjust_bounds(ax, tri.points)`

			`return ax.figure`


			`@_held_figure`
			`def convex_hull_plot_2d(hull, ax=None):`
			`"""`
			`Plot the given convex hull diagram in 2-D`

			`Parameters`
			`----------`
			`hull : scipy.spatial.ConvexHull instance`
			`Convex hull to plot`
			`ax : matplotlib.axes.Axes instance, optional`
			`Axes to plot on`

			`Returns`
			`-------`
			`fig : matplotlib.figure.Figure instance`
			`Figure for the plot`

			`See Also`
			`--------`
			`ConvexHull`

			`Notes`
			`-----`
			`Requires Matplotlib.`


			`Examples`
			`--------`

			`>>> import matplotlib.pyplot as plt`
			`>>> from scipy.spatial import ConvexHull, convex_hull_plot_2d`

			`The convex hull of a random set of points:`

			`>>> points = np.random.rand(30, 2)`
			`>>> hull = ConvexHull(points)`

			`Plot it:`

			`>>> _ = convex_hull_plot_2d(hull)`
			`>>> plt.show()`

			`"""`
			`from matplotlib.collections import LineCollection`

			`if hull.points.shape[1] != 2:`
			`raise ValueError("Convex hull is not 2-D")`

			`ax.plot(hull.points[:,0], hull.points[:,1], 'o')`
			`line_segments = [hull.points[simplex] for simplex in hull.simplices]`
			`ax.add_collection(LineCollection(line_segments,`
			`colors='k',`
			`linestyle='solid'))`
			`_adjust_bounds(ax, hull.points)`

			`return ax.figure`


			`@_held_figure`
			`def voronoi_plot_2d(vor, ax=None, **kw):`
			`"""`
			`Plot the given Voronoi diagram in 2-D`

			`Parameters`
			`----------`
			`vor : scipy.spatial.Voronoi instance`
			`Diagram to plot`
			`ax : matplotlib.axes.Axes instance, optional`
			`Axes to plot on`
			`show_points: bool, optional`
			`Add the Voronoi points to the plot.`
			`show_vertices : bool, optional`
			`Add the Voronoi vertices to the plot.`
			`line_colors : string, optional`
			`Specifies the line color for polygon boundaries`
			`line_width : float, optional`
			`Specifies the line width for polygon boundaries`
			`line_alpha: float, optional`
			`Specifies the line alpha for polygon boundaries`
			`point_size: float, optional`
			`Specifies the size of points`


			`Returns`
			`-------`
			`fig : matplotlib.figure.Figure instance`
			`Figure for the plot`

			`See Also`
			`--------`
			`Voronoi`

			`Notes`
			`-----`
			`Requires Matplotlib.`

			`Examples`
			`--------`
			`Set of point:`

			`>>> import matplotlib.pyplot as plt`
			`>>> points = np.random.rand(10,2) #random`

			`Voronoi diagram of the points:`

			`>>> from scipy.spatial import Voronoi, voronoi_plot_2d`
			`>>> vor = Voronoi(points)`

			using `voronoi_plot_2d` for visualisation:

			`>>> fig = voronoi_plot_2d(vor)`

			using `voronoi_plot_2d` for visualisation with enhancements:

			`>>> fig = voronoi_plot_2d(vor, show_vertices=False, line_colors='orange',`
			`... line_width=2, line_alpha=0.6, point_size=2)`
			`>>> plt.show()`

			`"""`
			`from matplotlib.collections import LineCollection`

			`if vor.points.shape[1] != 2:`
			`raise ValueError("Voronoi diagram is not 2-D")`

			`if kw.get('show_points', True):`
			`point_size = kw.get('point_size', None)`
			`ax.plot(vor.points[:,0], vor.points[:,1], '.', markersize=point_size)`
			`if kw.get('show_vertices', True):`
			`ax.plot(vor.vertices[:,0], vor.vertices[:,1], 'o')`

			`line_colors = kw.get('line_colors', 'k')`
			`line_width = kw.get('line_width', 1.0)`
			`line_alpha = kw.get('line_alpha', 1.0)`

			`center = vor.points.mean(axis=0)`
			`ptp_bound = vor.points.ptp(axis=0)`

			`finite_segments = []`
			`infinite_segments = []`
			`for pointidx, simplex in zip(vor.ridge_points, vor.ridge_vertices):`
			`simplex = np.asarray(simplex)`
			`if np.all(simplex >= 0):`
			`finite_segments.append(vor.vertices[simplex])`
			`else:`
			`i = simplex[simplex >= 0][0] # finite end Voronoi vertex`

			`t = vor.points[pointidx[1]] - vor.points[pointidx[0]] # tangent`
			`t /= np.linalg.norm(t)`
			`n = np.array([-t[1], t[0]]) # normal`

			`midpoint = vor.points[pointidx].mean(axis=0)`
			`direction = np.sign(np.dot(midpoint - center, n)) * n`
			`far_point = vor.vertices[i] + direction * ptp_bound.max()`

			`infinite_segments.append([vor.vertices[i], far_point])`

			`ax.add_collection(LineCollection(finite_segments,`
			`colors=line_colors,`
			`lw=line_width,`
			`alpha=line_alpha,`
			`linestyle='solid'))`
			`ax.add_collection(LineCollection(infinite_segments,`
			`colors=line_colors,`
			`lw=line_width,`
			`alpha=line_alpha,`
			`linestyle='dashed'))`

			`_adjust_bounds(ax, vor.points)`

			`return ax.figure`