# clipping a voronoi diagram python

I am computing a voronoi diagram from a set of points as follows:

``````from scipy.spatial import Voronoi
import numpy as np

np.random.seed(0)
points = np.random.uniform(-0.5, 0.5, (100, 2))
// Compute Voronoi
v = Voronoi(points)
voronoi_plot_2d(v)
plt.show()
``````

This creates an image as follows:

As one can see, this is creating vertices which are going to infinity (dashed lines) and also beyond the original bounding box for the points which is:

`````` bbox = np.array([[-0.5, -0.5], [0.5, -0.5], [0.5, 0.5], [-0.5, 0.5]])
``````

What I would like to do is clip the voronoi diagram to this bounding box i.e. project the out of bounds and infinite vertices onto the appropriate locations on this bounding box. So the vertices would need to be rearranged and projected back to the proper intersection points from infinity or the finite vertices but which are out of bounds from my clipping region.

• @unutbu Although it seems true that one can obtain the answer from the link to "Colorize Voronoi Diagram" the relation is not direct or obvious from my point of view. Luca made a similar question earlier and at the time I interpreted that he wanted only vertices inside a bounding box (and my answer at the time was for that). This time he seems to want the intercept points between bounding box and infinite regions of Voronoi. Not necessarily for plot purposes. I do not consider this to be a duplicate. – armatita Mar 17 '16 at 15:09
• I'm not sure if there's a more immediate way but check out code for intersection of two lines (example: stackoverflow.com/questions/20677795/…). Obviously you'll have to do it for each of the vertices that go into the infinite regions. – armatita Mar 17 '16 at 15:22
• @armatita and Luca: Sorry if I mistakenly closed this as a duplicate. – unutbu Mar 17 '16 at 15:27
• No harm done. Thanks for caring. – armatita Mar 17 '16 at 15:30
• Just to mention that I wrote a C++ version of what you want, it is available here. This also contains a user package for cgal-swig-bindings so a python version might not be too hard to have (though I only made the effort to make it work for java). – sloriot Mar 18 '16 at 15:30

It can be easyly be done with Shapely. You can install it from Conda Forge: `conda install shapely -c conda-forge`

Code you need at github.gist, based on answer by @Gabriel and @pv.:

``````# coding=utf-8
import numpy as np
import matplotlib.pyplot as plt
from scipy.spatial import Voronoi
from shapely.geometry import Polygon

"""
Reconstruct infinite voronoi regions in a 2D diagram to finite
regions.
Parameters
----------
vor : Voronoi
Input diagram
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)

# 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)

min_x = vor.min_bound[0] - 0.1
max_x = vor.max_bound[0] + 0.1
min_y = vor.min_bound[1] - 0.1
max_y = vor.max_bound[1] + 0.1

mins = np.tile((min_x, min_y), (vertices.shape[0], 1))
bounded_vertices = np.max((vertices, mins), axis=0)
maxs = np.tile((max_x, max_y), (vertices.shape[0], 1))
bounded_vertices = np.min((bounded_vertices, maxs), axis=0)

box = Polygon([[min_x, min_y], [min_x, max_y], [max_x, max_y], [max_x, min_y]])

# colorize
for region in regions:
polygon = vertices[region]
# Clipping polygon
poly = Polygon(polygon)
poly = poly.intersection(box)
polygon = [p for p in poly.exterior.coords]

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()
``````
• +1 for just answering after a long time. I will try and test it this week and accept if everything works1 – Luca Mar 26 '17 at 16:54