# How to efficiently find the bounding box of a collection of points?

I have several points stored in an array. I need to find bounds of that points ie. the rectangle which bounds all the points. I know how to solve this in plain Python.

I would like to know is there a better way than the naive max, min over the array or built-in method to solve the problem.

``````points = [[1, 3], [2, 4], [4, 1], [3, 3], [1, 6]]
b = bounds(points) # the function I am looking for
# now b = [[1, 1], [4, 6]]
``````
• Share how you would solve it in Python? We could try to improve upon it. How about : `np.min(points,0) and np.max(points,0)`? – Divakar Sep 21 '17 at 4:27
• Unless your data points have some kind of ordering already, you can't do better than O(n). So you may as well use naive min and max approach. – wim Sep 21 '17 at 4:33
• @Divakar That helped – ryanafrish7 Sep 21 '17 at 4:33

My approach to getting performance is to push things down to C level whenever possible:

``````def bounding_box(points):
x_coordinates, y_coordinates = zip(*points)

return [(min(x_coordinates), min(y_coordinates)), (max(x_coordinates), max(y_coordinates))]
``````

By my (crude) measure, this runs about 1.5 times faster than @ReblochonMasque's `bounding_box_naive()`. And is clearly more elegant. ;-)

You cannot do better than `O(n)`, because you must traverse all the points to determine the `max` and `min` for `x` and `y`.

But, you can reduce the constant factor, and traverse the list only once; however, it is unclear if that would give you a better execution time, and if it does, it would be for large collections of points.

### Here is the "naive" approach: (it is the fastest of the two)

``````def bounding_box_naive(points):
"""returns a list containing the bottom left and the top right
points in the sequence
Here, we use min and max four times over the collection of points
"""
bot_left_x = min(point for point in points)
bot_left_y = min(point for point in points)
top_right_x = max(point for point in points)
top_right_y = max(point for point in points)

return [(bot_left_x, bot_left_y), (top_right_x, top_right_y)]
``````

### and the (maybe?) less naive:

``````def bounding_box(points):
"""returns a list containing the bottom left and the top right
points in the sequence
Here, we traverse the collection of points only once,
to find the min and max for x and y
"""
bot_left_x, bot_left_y = float('inf'), float('inf')
top_right_x, top_right_y = float('-inf'), float('-inf')
for x, y in points:
bot_left_x = min(bot_left_x, x)
bot_left_y = min(bot_left_y, y)
top_right_x = max(top_right_x, x)
top_right_y = max(top_right_y, y)

return [(bot_left_x, bot_left_y), (top_right_x, top_right_y)]
``````

# profiling results:

``````import random
points = [(random.randrange(-1000, 1000), random.randrange(-1000, 1000))  for _ in range(1000000)]

%timeit bounding_box_naive(points)
%timeit bounding_box(points)
``````

### size = 1,000 points

``````1000 loops, best of 3: 573 µs per loop
1000 loops, best of 3: 1.46 ms per loop
``````

### size = 10,000 points

``````100 loops, best of 3: 5.7 ms per loop
100 loops, best of 3: 14.7 ms per loop
``````

### size 100,000 points

``````10 loops, best of 3: 66.8 ms per loop
10 loops, best of 3: 141 ms per loop
``````

### size 1,000,000 points

``````1 loop, best of 3: 664 ms per loop
1 loop, best of 3: 1.47 s per loop
``````

Clearly, the first "not so naive" approach is faster by a factor `2.5 - 3`

• +1, but I am curious how the performance of an inline ternary statement compares to a two-element `min` call -- or, just an `if: (update assignment)` in the case it's larger/smaller – jedwards Sep 21 '17 at 5:02
• 4 loops and 1 comparison inside each loop vs 1 loop and 4 comparisons inside the loop. I think it's just "moving work around". If you really want speed, you should be looking at a numba JIT or something like that. – wim Sep 21 '17 at 5:13
• hehehe, that was my guess too, but after your comment, I had to go back to it and measure it. Thanks for pushing me @wim. (the results are posted above) – Reblochon Masque Sep 21 '17 at 5:26