# Verify that all edges in a 2D graph are sufficiently far from each other

I have a graph where each node has coordinates in 2D (it's actually a geographic graph, with latitude and longitude.) I need to verify that if the distance between two edges is less than MAX_DIST then they share a node. Of course, if they intersect, then the distance between them is zero.

The brute force algorithm is trivial, is there a more efficient algorithm?

I was thinking of trying to adapt https://en.wikipedia.org/wiki/Closest_pair_of_points_problem to graph edges (and ignoring pairs of edges with a shared node), but it is not trivial to do so.

• How about adding all edges to a Rtree index; afterwards you would only need to check the closest edges for MAX_DIST instead of all of them. – Ionut Ticus Mar 7 '20 at 16:51
• I don't know how an Rtree with all the edges would help me find the closest edges – lorg Mar 7 '20 at 21:52
• After creating the index you can use functions like `get_nearest_objects(bbox)` which is a lot faster than manually checking all other edges; think of it like a regular index you use when working with a database. I can try to run some tests if you can provide some test data. – Ionut Ticus Mar 8 '20 at 10:49

## 1 Answer

I was curios to see how the rtree index idea would perform so I created a small script to test it using two really cool libraries for Python: Rtree and shapely
The snippet generates 1000 segments with 1 < length < 5 and coordinates in the [0, 100] interval, populates the index and then counts the pairs that are closer than MAX_DIST==0.1 (using the classic and the index-based method).
In my tests the index method was around 25x faster using the conditions above; this might vary greatly for your data set but the result is encouraging:

``````found 532 pairs of close segments using classic method
7.47 seconds for classic count
found 532 pairs of close segments using index method
0.28 seconds for index count
``````

The performance and correctness of the index method depends on how your segments are distributed (how many are close, if you have very long segments, the parameters used).

``````import time
import random
from rtree import Rtree
from shapely.geometry import LineString

def generate_segments(number):
segments = {}
for i in range(number):
while True:
x1 = random.randint(0, 100)
y1 = random.randint(0, 100)
x2 = random.randint(0, 100)
y2 = random.randint(0, 100)
segment = LineString([(x1, y1), (x2, y2)])
if 1 < segment.length < 5:  # only add relatively small segments
segments[i] = segment
break
return segments

def populate_index(segments):
idx = Rtree()
for index, segment in segments.items():
idx.add(index, segment.bounds)
return idx

def count_close_segments(segments, max_distance):
count = 0
for i in range(len(segments)-1):
s1 = segments[i]
for j in range(i+1, len(segments)):
s2 = segments[j]
if s1.distance(s2) < max_distance:
count += 1
return count

def count_close_segments_index(segments, idx, max_distance):
count = 0
for index, segment in segments.items():
close_indexes = idx.nearest(segment.bounds, 10)
for close_index in close_indexes:
if index >= close_index:  # do not count duplicates
continue
close_segment = segments[close_index]
if segment.distance(close_segment) < max_distance:
count += 1
return count

if __name__ == "__main__":
MAX_DIST = 0.1
s = generate_segments(1000)
r_idx = populate_index(s)
t = time.time()
print("found %d pairs of close segments using classic method" % count_close_segments(s, MAX_DIST))
print("%.2f seconds for classic count" % (time.time() - t))
t = time.time()
print("found %d pairs of close segments using index method" % count_close_segments_index(s, r_idx, MAX_DIST))
print("%.2f seconds for index count" % (time.time() - t))
``````
• Very cool! I actually figured out how to use rtree to solve this problem, I will review your solution as well, really awesome :) – lorg Mar 12 '20 at 16:29