# Efficient way to find overlapping of N rectangles

I am trying to find an efficient solution for finding overlapping of n rectangles where rectangles are stored in two separate lists. We are looking for all rectangles in `listA` that overlap with rectangles in `listB` (and vice versa). Comparing one element from the first list to second list could take immensely large amount of time. I am looking for an efficient solution.

I have two list of rectangles

``````rect = Rectangle(10, 12, 56, 15)
rect2 = Rectangle(0, 0,1, 15)
rect3 = Rectangle (10,  12, 56, 15)

listA = [rect, rect2]
listB = [rect3]
``````

which is created from the class:

``````import numpy as np
import itertools as it

class  Rectangle(object):
def __init__(self, left, right, bottom, top):
self.left = left
self.bottom = right
self.right = bottom
self.top = top

def overlap(r1, r2):
hoverlaps = True
voverlaps = True
if (r1.left > r2.right) or (r1.right < r2.left):
hoverlaps = False
if (r1.top < r2.bottom) or (r1.bottom > r2.top):
voverlaps = False
return hoverlaps and voverlaps
``````

I need to compare rectangle in `listA` to `listB` the code goes like this which is highly inefficient - comparing one by one

``````for a in it.combinations(listB):
for b in it.combinations(listA):
if a.overlap(b):
``````

Any better efficient method to deal with the problem?

• Try `[rect]` instead. It seems to be what you want to do. – Jed Fox Nov 16 '16 at 0:20
• `list_of_rectangles = [rect, rect2]`. Or `list_of_rectangles = list()` `list_of_rectangles.append(rect)` `list_of_rectangles.append(rect2)` on 3 separate lines. – PM 2Ring Nov 16 '16 at 0:41
• You are expected to 1) give a forum a fair chance to answer a question (my take: 60 hours at least, 8 days welcome) 2) plant cross-references yourself. – greybeard Nov 18 '16 at 8:32
• Can rectangles in each list overlap? – n. 'pronouns' m. Nov 18 '16 at 9:23
• @nm yes. Each list can overlap – karu Nov 18 '16 at 9:31

First off: As with many a problem from computational geometry, specifying the parameters for order-of-growth analysis needs care: calling the lengths of the lists m and n, the worst case in just those parameters is Ω(m×n), as all areas might overlap (in this regard, the algorithm from the question is asymptotically optimal). It is usual to include the size of the output: t = f(m, n, o) (Output-sensitive algorithm).
Trivially, f ∈ Ω(m+n+o) for the problem presented.

Line Sweep is a paradigm to reduce geometrical problems by one dimension - in its original form, from 2D to 1D, plane to line.

Imagine all the rectangles in the plane, different colours for the lists.
Now sweep a line across this plane - left to right, conventionally, and infinitesimally further to the right "for low y-coordinates" (handle coordinates in increasing x-order, increasing y-order for equal x).
For all of this sweep (or scan), per colour keep one set representing the "y-intervals" of all rectangles at the current x-coordinate, starting empty. (In a data structure supporting insertion, deletion, and enumerating all intervals that overlap a query interval: see below.)
Meeting the left side of a rectangle, add the segment to the data structure for its colour. Report overlapping intervals/rectangles in any other colour.
At a right side, remove the segment.
Depending on the definition of "overlapping", handle left sides before right sides - or the other way round.

There are many data structures supporting insertion and deletion of intervals, and finding all intervals that overlap a query interval. Currently, I think Augmented Search-Trees may be easiest to understand, implement, test, analyse…
Using this, enumerating all o intersecting pairs of axis-aligned rectangles (a, b) from `listA` and `listB` should be possible in O((m+n)log(m+n)+o) time and O(m+n) space. For sizeable problem instances, avoid data structures needing more than linear space ((original) Segment Trees, for one example pertaining to interval overlap).

Another paradigm in algorithm design is Divide&Conquer: with a computational geometry problem, choose one dimension in which the problem can be divided into independent parts, and a coordinate such that the sub-problems for "coordinates below" and "coordinates above" are close in expected run-time. Quite possibly, another (and different) sub-problem "including the coordinate" needs to be solved. This tends to be beneficial when a) the run-time for solving sub-problems is "super-log-linear", and b) there is a cheap (linear) way to construct the overall solution from the solutions for the sub-problems.
This lends itself to concurrent problem solving, and can be used with any other approach for sub-problems, including line sweep.

There will be many ways to tweak each approach, starting with disregarding input items that can't possibly contribute to the output. To "fairly" compare implementations of algorithms of like order of growth, don't aim for a fair "level of tweakedness": try to invest fair amounts of time for tweaking.

• An animation of the sweep-line algorithm as applied to the problem of rectangle intersection can be found can be found here The implementation is in Javascript, should be easily portable to Python. This program finds intersections within a single list, as opposed to between two lists, but this shouldn't matter much. – n. 'pronouns' m. Nov 18 '16 at 10:21
• @n.m. I intended to look for something like that (seems to need scripting enabled for ocks.org & d3js.org, btw.), but including inclusion (overlap without intersecting edges) and the operation of the segment tree, too. `finds intersections within a single list, as opposed to between two lists, but this shouldn't matter much` Not much, then again, it is the only excuse not to flag this as a duplicate. – greybeard Nov 18 '16 at 10:28
• This method handles overlap without intersecting edges no problem. – n. 'pronouns' m. Nov 18 '16 at 17:54
• This=sweepline. The animation only shows line intersections but inclusion is handled naturally by the algorithm. – n. 'pronouns' m. Nov 18 '16 at 18:41
• Since search/insert/delete in a balanced tree is log(N), the complexity appears to be O((m+n)*log(m+n)). – ivan_pozdeev Nov 19 '16 at 13:48

A couple of potential minor efficiency improvements. First, fix your `overlap()` function, it potentially does calculations it needn't:

``````def overlap(r1, r2):

if r1.left > r2.right or r1.right < r2.left:
return False

if r1.top < r2.bottom or r1.bottom > r2.top:
return False

return True
``````

Second, calculate the contaning rectangle for one of the lists and use it to screen the other list -- any rectangle that doesn't overlap the container doesn't need to be tested against all the rectangles that contributed to it:

``````def containing_rectangle(rectangles):
return Rectangle(min(rectangles, key=lambda r: r.left).left,
max(rectangles, key=lambda r: r.right).right,
min(rectangles, key=lambda r: r.bottom).bottom,
max(rectangles, key=lambda r: r.top).top
)

c = containing_rectangle(listA)

for b in listB:
if b.overlap(c):
for a in listA:
if b.overlap(a):
``````

In my testing with hundreds of random rectangles, this avoided comparisons on the order of single digit percentages (e.g. 2% or 3%) and occasionally increased the number of comparisons. However, presumably your data isn't random and might fare better with this type of screening.

Depending on the nature of your data, you could break this up into a container rectangle check for each batch of 10K rectangles out of 50K or what ever slice gives you maximum efficiency. Possibly presorting the rectangles (e.g. by their centers) before assigning them to container batches.

We can break up and batch both lists with container rectangles:

``````listAA = [listA[x:x + 10] for x in range(0, len(listA), 10)]

for i, arrays in enumerate(listAA):
listAA[i] = [containing_rectangle(arrays)] + arrays

listBB = [listB[x:x + 10] for x in range(0, len(listB), 10)]

for i, arrays in enumerate(listBB):
listBB[i] = [containing_rectangle(arrays)] + arrays

for bb in listBB:
for aa in listAA:
if bb.overlap(aa):
for b in bb[1:]:
if b.overlap(aa):
for a in aa[1:]:
if b.overlap(a):
``````

With my random data, this decreased the comparisons on the order of 15% to 20%, even counting the container rectangle comparisons. The batching of rectangles above is arbitrary and you can likely do better.

The exception you're getting comes from the last line of the code you show. The expression `list[rect]` is not valid, since `list` is a class, and the `[]` syntax in that context is trying to index it. You probably want just `[rect]` (which creates a new list containing the single item `rect`).

There are several other basic issues, with your code. For instance, your `Rect.__init__` method doesn't set a `left` attribute, which you seem to expect in your collision testing method. You've also used different capitalization for `r1` and `r2` in different parts of the `overlap` method (Python doesn't consider `r1` to be the same as `R1`).

Those issues don't really have anything to do with testing more than two rectangles, which your question asks about. The simplest way to do that (and I strongly advise sticking to simple algorithms if you're having basic issues like the ones mentioned above), is to simply compare each rectangle with each other rectangle using the existing pairwise test. You can use `itertools.combinations` to easily get all pairs of items from an iterable (like a list):

``````list_of_rects = [rect1, rect2, rect3, rect4] # assume these are defined elsewhere

for a, b in itertools.combinations(list_of_rects, 2):
if a.overlap(b):
# do whatever you want to do when two rectangles overlap here
``````
• That means there are more efficient algorithms are there to solve that problem. Could you please suggest me those algorithms? I am sure that my solution would be extremely inefficient – karu Nov 16 '16 at 7:55
• For a relatively small number of rectangles (e.g. 10 or 20 rather than 10000), the performance of this algorithm will be fine. Don't worry about performance for bigger problems unless you are absolutely certain that you need to (e.g. because you've tried the simple algorithm and it was too slow). – Blckknght Nov 16 '16 at 12:51
• I have more than 50000 rectangles to check. I could update the code – karu Nov 16 '16 at 12:53

This implementation using numpy is about 35-40 times faster according to a test I did. For 2 lists each with 10000 random rectangles this method took 2.5 secs and the method in the question took ~90 sec. In terms of complexity it's still O(N^2) like the method in the question.

``````import numpy as np

rects1=[
[0,10,0,10],
[0,100,0,100],
]

rects2=[
[20,50,20,50],
[200,500,200,500],
[0,12,0,12]
]

data=np.asarray(rects2)

def find_overlaps(rect,data):
data=data[data[::,0]<rect]
data=data[data[::,1]>rect]
data=data[data[::,2]<rect]
data=data[data[::,3]>rect]
return data

for rect in rects1:
overlaps = find_overlaps(rect,data)
for overlap in overlaps:
pass#do something here
``````

Obviously, if your list (at least listB) is sorted by r2.xmin, you can search for r1.xmax in listB and stop testing overlap of r1 in this listB (the rest will be to the right). This will be O(n·log(n)).

A sorted vector has faster access than a sorted list.

I'm supposing that the rectangles edges are oriented same as axis.

Also fix your `overlap()` function as cdlane explained.

If you know the upper and lower limits for coordinates, you can narrow the search by partitioning the coordinate space into squares e.g. 100x100.

• Make one "set" per coordinate square.
• Go through all squares, putting them in the "set" of any square they overlap.

See also Tiled Rendering which uses partitions to speed up graphical operations.

``````    // Stores rectangles which overlap (x, y)..(x+w-1, y+h-1)
public class RectangleSet
{
private List<Rectangle> _overlaps;

public RectangleSet(int x, int y, int w, int h);
}

// Partitions the coordinate space into squares
public class CoordinateArea
{
private const int SquareSize = 100;

public List<RectangleSet> Squares = new List<RectangleSet>();

public CoordinateArea(int xmin, int ymin, int xmax, int ymax)
{
for (int x = xmin; x <= xmax; x += SquareSize)
for (int y = ymin; y <= ymax; y += SquareSize)
{
}
}

// Adds a list of rectangles to the coordinate space
{
foreach (Rectangle r in list)
{
foreach (RectangleSet set in Squares)
{
if (r.Overlaps(set))
}
}
}
}
``````

Now you have a much smaller set of rectangles for comparison, which should speed things up nicely.

``````CoordinateArea A = new CoordinateArea(-500, -500, +1000, +1000);
CoordinateArea B = new CoordinateArea(-500, -500, +1000, +1000);  // same limits for A, B

for (int i = 0; i < listA.Squares.Count; i++)
{
RectangleSet setA = A[i];
RectangleSet setB = B[i];

// *** small number of rectangles, which you can now check thoroghly for overlaps ***

}
``````

I think you have to setup an additional data structure (spatial index) in order to have fast access to nearby rectangles that potentially overlap in order to reduce the time complexity from quadratic to linearithmic.

• (You don't exactly need to add an answer to add something to an answer: use the edit button.) There a set_/_static problems, and there are query_/_dynamic problems: this question stated a set problem; the links are about query problems, far as I can tell. (Query algorithms give an upper bound for set problem complexity.) – greybeard Nov 18 '16 at 11:26
• @greybeard, you are right. However, often the same data structure can be used for an efficient solution of a set problem. Instead of using it for individual queries, the same data structure often can be used for an iteration that solves the set problem. A spatial index could be used to iterate over pairs of rectangles that are candidates for overlapping. – otmar Nov 18 '16 at 11:53

Here is what I use to calculate overlap areas of many candidate rectangles (with candidate_coords [[l, t, r, b], ...]) with a target one (target_coords [l, t, r, b]):

``````comb_tensor = np.zeros((2, candidate_coords.shape, 4))

comb_tensor[0, :] = target_coords
comb_tensor = candidate_coords

dx = np.amin(comb_tensor[:, :, 2].T, axis=1) - np.amax(comb_tensor[:, :, 0].T, axis=1)
dy = np.amin(comb_tensor[:, :, 3].T, axis=1) - np.amax(comb_tensor[:, :, 1].T, axis=1)

dx[dx < 0] = 0
dy[dy < 0] = 0

overlap_areas = dx * dy
``````

This should be fairly efficient especially if there are many candidate rectangles as all is done using numpy functions operating on ndarrays. You can either do a loop calculating the overlap areas or perhaps add one more dimension to comb_tensor.