pv · June 27, 2024 22:07 · fxn342 · Jun 27, 2024
diff --git a/colorized_voronoi.py b/colorized_voronoi.py
 import numpy as np
 import matplotlib.pyplot as plt
 from scipy.spatial import Voronoi

 def voronoi_finite_polygons_2d(vor, radius=None):
    """
    Reconstruct infinite voronoi regions in a 2D diagram to finite
    regions.

    Parameters
    ----------
    vor : Voronoi
        Input diagram
    radius : float, optional
        Distance to 'points at infinity'.

    Returns
    -------
    regions : list of tuples
        Indices of vertices in each revised Voronoi regions.
    vertices : list of tuples
        Coordinates for revised Voronoi vertices. Same as coordinates
        of input vertices, with 'points at infinity' appended to the
        end.

    """

    if vor.points.shape[1] != 2:
        raise ValueError("Requires 2D input")

    new_regions = []
    new_vertices = vor.vertices.tolist()

    center = vor.points.mean(axis=0)
    if radius is None:
        radius = vor.points.ptp().max()*2

    # Construct a map containing all ridges for a given point
    all_ridges = {}
    for (p1, p2), (v1, v2) in zip(vor.ridge_points, vor.ridge_vertices):
        all_ridges.setdefault(p1, []).append((p2, v1, v2))
        all_ridges.setdefault(p2, []).append((p1, v1, v2))

    # Reconstruct infinite regions
    for p1, region in enumerate(vor.point_region):
        vertices = vor.regions[region]

        if all(v >= 0 for v in vertices):
            # finite region
            new_regions.append(vertices)
            continue

        # reconstruct a non-finite region
        ridges = all_ridges[p1]
        new_region = [v for v in vertices if v >= 0]

        for p2, v1, v2 in ridges:
            if v2 < 0:
                v1, v2 = v2, v1
            if v1 >= 0:
                # finite ridge: already in the region
                continue

            # Compute the missing endpoint of an infinite ridge

            t = vor.points[p2] - vor.points[p1] # tangent
            t /= np.linalg.norm(t)
            n = np.array([-t[1], t[0]])  # normal

            midpoint = vor.points[[p1, p2]].mean(axis=0)
            direction = np.sign(np.dot(midpoint - center, n)) * n
            far_point = vor.vertices[v2] + direction * radius

            new_region.append(len(new_vertices))
            new_vertices.append(far_point.tolist())

        # sort region counterclockwise
        vs = np.asarray([new_vertices[v] for v in new_region])
        c = vs.mean(axis=0)
        angles = np.arctan2(vs[:,1] - c[1], vs[:,0] - c[0])
        new_region = np.array(new_region)[np.argsort(angles)]

        # finish
        new_regions.append(new_region.tolist())

    return new_regions, np.asarray(new_vertices)

 # make up data points
 np.random.seed(1234)
 points = np.random.rand(15, 2)

 # compute Voronoi tesselation
 vor = Voronoi(points)

 # plot
 regions, vertices = voronoi_finite_polygons_2d(vor)
 print "--"
 print regions
 print "--"
 print vertices

 # colorize
 for region in regions:
    polygon = vertices[region]
    plt.fill(*zip(*polygon), alpha=0.4)

 plt.plot(points[:,0], points[:,1], 'ko')
 plt.axis('equal')
 plt.xlim(vor.min_bound[0] - 0.1, vor.max_bound[0] + 0.1)
 plt.ylim(vor.min_bound[1] - 0.1, vor.max_bound[1] + 0.1)

 plt.savefig('voro.png')
 plt.show()
	import numpy as np
	import matplotlib.pyplot as plt
	from scipy.spatial import Voronoi

	def voronoi_finite_polygons_2d(vor, radius=None):
	"""
	Reconstruct infinite voronoi regions in a 2D diagram to finite
	regions.

	Parameters
	----------
	vor : Voronoi
	Input diagram
	radius : float, optional
	Distance to 'points at infinity'.

	Returns
	-------
	regions : list of tuples
	Indices of vertices in each revised Voronoi regions.
	vertices : list of tuples
	Coordinates for revised Voronoi vertices. Same as coordinates
	of input vertices, with 'points at infinity' appended to the
	end.

	"""

	if vor.points.shape[1] != 2:
	raise ValueError("Requires 2D input")

	new_regions = []
	new_vertices = vor.vertices.tolist()

	center = vor.points.mean(axis=0)
	if radius is None:
	radius = vor.points.ptp().max()*2

	# Construct a map containing all ridges for a given point
	all_ridges = {}
	for (p1, p2), (v1, v2) in zip(vor.ridge_points, vor.ridge_vertices):
	all_ridges.setdefault(p1, []).append((p2, v1, v2))
	all_ridges.setdefault(p2, []).append((p1, v1, v2))

	# Reconstruct infinite regions
	for p1, region in enumerate(vor.point_region):
	vertices = vor.regions[region]

	if all(v >= 0 for v in vertices):
	# finite region
	new_regions.append(vertices)
	continue

	# reconstruct a non-finite region
	ridges = all_ridges[p1]
	new_region = [v for v in vertices if v >= 0]

	for p2, v1, v2 in ridges:
	if v2 < 0:
	v1, v2 = v2, v1
	if v1 >= 0:
	# finite ridge: already in the region
	continue

	# Compute the missing endpoint of an infinite ridge

	t = vor.points[p2] - vor.points[p1] # tangent
	t /= np.linalg.norm(t)
	n = np.array([-t[1], t[0]]) # normal

	midpoint = vor.points[[p1, p2]].mean(axis=0)
	direction = np.sign(np.dot(midpoint - center, n)) * n
	far_point = vor.vertices[v2] + direction * radius

	new_region.append(len(new_vertices))
	new_vertices.append(far_point.tolist())

	# sort region counterclockwise
	vs = np.asarray([new_vertices[v] for v in new_region])
	c = vs.mean(axis=0)
	angles = np.arctan2(vs[:,1] - c[1], vs[:,0] - c[0])
	new_region = np.array(new_region)[np.argsort(angles)]

	# finish
	new_regions.append(new_region.tolist())

	return new_regions, np.asarray(new_vertices)

	# make up data points
	np.random.seed(1234)
	points = np.random.rand(15, 2)

	# compute Voronoi tesselation
	vor = Voronoi(points)

	# plot
	regions, vertices = voronoi_finite_polygons_2d(vor)
	print "--"
	print regions
	print "--"
	print vertices

	# colorize
	for region in regions:
	polygon = vertices[region]
	plt.fill(zip(polygon), alpha=0.4)

	plt.plot(points[:,0], points[:,1], 'ko')
	plt.axis('equal')
	plt.xlim(vor.min_bound[0] - 0.1, vor.max_bound[0] + 0.1)
	plt.ylim(vor.min_bound[1] - 0.1, vor.max_bound[1] + 0.1)

	plt.savefig('voro.png')
	plt.show()