# Dynamic and/or Static Rectilinear/Orthogonal/X-Y Convex Hull

I'm looking for an efficient algorithm for handling 2D dynamic rectilinear convex hulls.

I've coded up a static algorithm, but while it works in most cases, it doesn't work in all, so I'm also looking for resources on static rectilinear convex hulls. Wikipedia has some research papers on algorithms, but I can't access them. So looking for other sources or help writing up the code.

Any help would be appreciated, an algorithm in Python, most appreciated.

Current static Code:

``````def stepped_hull(points, is_sorted=False, return_sections=False):
# May be equivalent to the orthogonal convex hull

if not is_sorted:
points = sorted(set(points))

if len(points) <= 1:
return points

# Get extreme y points
min_y = min(points, lambda p:p[1])
max_y = max(points, lambda p:p[1])

points_reversed = list(reversed(points))

# Create upper section
upper_left = build_stepped_upper(points, max_y)
upper_right = build_stepped_upper(points_reversed, max_y)

# Create lower section
lower_left = build_stepped_lower(points, min_y)
lower_right = build_stepped_lower(points_reversed, min_y)

# Correct the ordering
lower_right.reverse()
upper_left.reverse()

if return_sections:
return lower_left, lower_right, upper_right, upper_left

# Remove duplicate points
hull = OrderedSet(lower_left + lower_right + upper_right + upper_left)
return list(hull)

def build_stepped_upper(points, max_y):
# Steps towards the highest y point

section = [points[0]]

if max_y != points[0]:
for point in points:
if point[1] >= section[-1][1]:
section.append(point)

if max_y == point:
break
return section

def build_stepped_lower(points, min_y):
# Steps towards the lowest y point

section = [points[0]]

if min_y != points[0]:
for point in points:
if point[1] <= section[-1][1]:
section.append(point)

if min_y == point:
break
return section
``````
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By dynamic do you mean you want to maintain a x-y convex hull where its points are modified along the program execution ? Do you mean your static algorithms works, but it fails for updating the convex hull, or does it fail on something else ? –  mmgp Jan 19 '13 at 2:07
Basically, I want to create a x-y hull from a set of points, remove 1 or more hull points, recalculate the hull. Remove some sort points recalculate, so on and so on. I'd like to avoid deleting points at O(N log N), O(N) might be workable, O(log N) ideal. I'm currently using an static algorithm that gives the correct points, but due to the way I coded it, may have crossed edges in the case where a point is extreme point for both x and y. A relatively minor issue, but a sign that the algorithm may be flawed in other ways. Hence would prefer a known "correct" algorithm if possible. –  Nuclearman Jan 19 '13 at 2:16
I confess I haven't implemented algorithms for this kind of convex hull, but is it unique (considering a single plane orientation) ? For example, if you have two points, `a` and `b`, in the same x coordinate with distinct y coordinates, can you simply link a point `c` that is to the left of both points, and also below both of them, to the uppermost between `a` and `b` ? Or is there a requirement to connect `c` first to the bottom most of them first ? –  mmgp Jan 19 '13 at 2:22
Connecting to the uppermost in that situation would create a convex hull that has an area greater than the one done by the other method. Does that disqualify the former as a x-y convex hull ? –  mmgp Jan 19 '13 at 2:23
The algorithm I'm using to check which points to remove, relies on the proper ordering so c-b-a is required, which is why the minor issue I have with the static algorithm is problematic. Although, now that you mention it, that might be an issue with obtaining algorithms much better than O(N) algorithms –  Nuclearman Jan 19 '13 at 2:33
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