I am trying to find the centroid of a set of points under the Chebyshev distance. I wrote a program that apparently works for the cases that I tried but apparently gives incorrect answers for some edge cases that I do not have access to. [Meta remark: I would have marked this homework, but the tag is being obsoleted]

To get to the chase, the centroid is the point which has a minimum average distance to the set of points. The Chebyshev distance of two points p and q in two dimensions is

Also, I am restricted to points with integral co-ordinates.

This is my code:

```
sum_x=0; sum_y=0
for p in points:
sum_x = sum_x + p[0]
sum_y = sum_y + p[1]
center_x = int(sum_x/N)
center_y = int(sum_y/N)
directions = [(-1,-1),
(-1,0),
(-1,1),
(0,-1),
(0,0),
(0,1),
(1,-1),
(1,0),
(1,1)]
distances = [0] * len(directions)
for p in points:
for i in range(len(directions)):
distances[i] = distances[i] + max(abs(center_x+directions[i][0]-p[0]),abs(center_y+directions[i][1]-p[1]))
best_direction = min(range(len(directions)), key = lambda i:distances[i])
print "centroid = (", center_x+directions[best_direction][0],",", center_y+directions[best_direction][1],")"
print "total distance = ", distances[best_direction]
```

Here is my rationale: The Chebyshev metric is the same as the Manhattan distance under rotation in 2 dimensions. I basically find the Manhattan centroid, which is the same as the regular average of points, and then just search among the adjacent integral points to get the actual Chebyshev centroid. But I can't seem to find a bug in my code.