# Regular space subdivision

I am writing an application which subdivides an N-dimensional axis aligned bounding box into smaller N-dimensional bounding boxes, I need an algorithm which will do this.
For example:

in 1 dimension a "bounding box" is simply a length
e.g. { Min=0, Max=100 }
which would be subdivided into
{Min=0, Max=50} and {Min=50, Max=100}

in 2 dimensions a "bounding box" is a square
e.g. {Min=[0,0], Max=[100,100]}
would be divided into
{Min=[0,0], Max=[50,50]}
{Min=[0,50], Max=[50,100]}
{Min=[50,0], Max=[100,50]}
{Min=[50,50], Max=[100,100]}

And so on, all I need is a description of an algorithm for doing this, language doesn't particularly matter, since once I know how to do it I can translate it into the language of choice (C# in this case)

EDIT:: In response to questions in comments:

• subdivisions must always be equal (as in the examples)
• boundaries are floating points, so divisibility by two isn't a problem
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do you need arbitrary subdivision or do you always want to split it's dimension's length by two as you did in your examples? –  Savvas Dalkitsis Sep 8 '09 at 22:24
An what do you do if the dimension is not divisible by 2 (or the number of subdivisions). If the boundaries are not integers this may not matter much. –  Kathy Van Stone Sep 8 '09 at 22:36

Break it into two problems: iterating over the grid of "Min" points, and constructing a small box for a Min point.

For your second case, {[0,0], [100,100]}, deltaX=50 and deltaY=50. The grid is

```[0,   0]
[0,  50]
[50,  0]
[50, 50]
```

and it is trivial to construct the second column from the first:

```[ 0,  0] [ 50,  50]
[ 0, 50] [ 50, 100]
[50,  0] [100,  50]
[50, 50] [100, 100]
```

Here's a three-dimensional case {[0,0,0], [100,100,60]}, delta = [50, 50, 30]

```[ 0,  0,  0] [ 50,  50, 30]
[ 0,  0, 30] [ 50,  50, 60]
[ 0, 50,  0] [ 50, 100, 30]
[ 0, 50, 30] [ 50, 100, 60]
[50,  0,  0] [100,  50, 30]
[50,  0, 30] [100,  50, 60]
[50, 50,  0] [100, 100, 30]
[50, 50, 30] [100, 100, 60]
```
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I must admit as I was typing the question out, a solution a little like this occurred to me, I wonder if this is the best way? :/ –  Martin Sep 8 '09 at 22:47

A function that splits the box in all dimensions (in Python):

``````def halfboxes(box):
result = [[]]
for (a, b) in box:
result = [r + [(a, (a+b)/2)] for r in result] + \
[r + [((a+b)/2, b)] for r in result]
return result

h = halfboxes([(0,100), (20, 100)])

# Results in h =
#   [[(0, 50), (20, 60)],  [(50, 100), (20, 60)],
#    [(0, 50), (60, 100)], [(50, 100), (60,100)]]
``````

If this is's a good solution also depends your performance requirements. It makes a lot copies of arrays, which is not really efficient. But it might well be good enough for your use case.

### Edit:

A more efficient version, that doesn't copy any arrays:

``````def halfboxes(box):
# total number of resulting arrays
resultscount = 2**len(box)

# allocate |resultscount| arrays
results = [[] for i in range(resultscount)]

for (a,b) in box:
low  = (a, (a+b)/2)
high = ((a+b)/2, b)
for i in range(resultscount):
# "magic" to append the high/low parts to the correct array
results[i].append(low)
else:
results[i].append(high)
return results
``````

Here no arrays are copied and some calculations on the index are used to decide where the new boundaries should be added.

-
Unfortunately this is for games (space subdivision is useful for a whole range of tasks), so performance is vital. –  Martin Sep 8 '09 at 22:50
• calculate the first box:

dimension n: Min[0, 0, 0, .., 0] -- Max[delta1/2, delta2/2, ..., deltan/2]

• your big box will be subdivised to 2n small boxes -> calculate 2n transalations to apply to the 1st box (including a translation of [0, 0, 0, .., 0])

(of course the code below is not optimized-organized...)

``````using System;
using System.Collections.Generic;

namespace WindowsFormsApplication1
{
public class Class1
{
public static List<Box> GetSmallBoxes(Box bigBox)
{
int translationCoef;
List<Box> boxes = new List<Box>();
Box box;

for (int k = 0; k < Math.Pow(2, bigBox.Dimension); k++)
{
box = new Box(bigBox.Dimension);

for (int d = 0; d < bigBox.Dimension; d++)
{
translationCoef = ((int)(k / Math.Pow(2, bigBox.Dimension - d - 1)) % 2) == 0 ? 1 : 0;

box.Mins[d] = bigBox.Mins[d] + (bigBox.Deltas[d] / 2) * translationCoef;
box.Maxs[d] = bigBox.Mins[d] + (bigBox.Deltas[d] / 2) * (1 + translationCoef);
}

}

return boxes;
}

public static void Main()
{
Box bigBox = new Box(5);
bigBox.Mins = new int[] { 0, 10, 30, 20, 40 };
bigBox.Maxs = new int[] { 80, 50, 110, 40, 50 };
List<Box> smallBoxes = Class1.GetSmallBoxes(bigBox);
}
}

public class Box
{
public int Dimension;
public int[] Mins;
public int[] Maxs;

public Box(int dimension)
{
Dimension = dimension;
Mins = new int[dimension];
Maxs = new int[dimension];
}

public int[] Deltas
{
get
{
int[] deltas = new int[Dimension];
for (int i = 0; i < Dimension; i++)
{
deltas[i] = Maxs[i] - Mins[i];
}
return deltas;
}
}

public override string ToString()
{
string str;
str = "Min[";
foreach (int min in Mins)
{
str += min.ToString() + ", ";
}
str = str.Substring(0, str.Length - 2);
str += "] -- Max[";
foreach (int max in Maxs)
{
str += max.ToString() + ", ";
}
str = str.Substring(0, str.Length - 2);
return str;
}
}
}
``````
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