# Overlapping cubes

I'm trying to determine if two cubes overlap. I've read up on overlapping rectangles, but I'm not sure how to translate it into the third dimension.

My goal is to generate a number of randomly positioned and sized non-overlapping cubes.

These cubes are represented on a x,y,z Cartesian plane.

The accepted answer is wrong and very confusing. Here is what I have come up with.

Determining overlap in the x plane

``````    if (cubeA.maxX > cubeB.minX)
if (cubeA.minX < cubeB.maxX)
``````

Determining overlap in the y plane

``````    if (cubeA.maxY > cubeB.minY)
if (cubeA.minY < cubeB.maxY)
``````

Determining overlap in the z plane

``````    if (cubeA.maxZ > cubeB.minZ)
if (cubeA.minZ < cubeB.maxZ)
``````

if you AND all of these conditions together and the result is true, you know that the cubes intersect at some point.

You should be able to modify Determine if two rectangles overlap each other? to your purpose fairly easily.

Suppose that you have `CubeA` and `CubeB`. Any one of 6 conditions guarantees that no overlap can exist:

``````Cond1.  If A's left face is to the right of the B's right face,
-  then A is Totally to right Of B
CubeA.X2 < CubeB.X1
Cond2.  If A's right face is to the left of the B's left face,
-  then A is Totally to left Of B
CubeB.X2 < CubeA.X1
Cond3.  If A's top face is below B's bottom face,
-  then A is Totally below B
CubeA.Z2 < CubeB.Z1
Cond4.  If A's bottom face is above B's top face,
-  then A is Totally above B
CubeB.Z2 < CubeA.Z1
Cond5.  If A's front face is behind B's back face,
-  then A is Totally behind B
CubeA.Y2 < CubeB.Y1
Cond6.  If A's left face is to the left of B's right face,
-  then A is Totally to the right of B
CubeB.Y2 < CubeA.Y1
``````

So the condition for no overlap is:

``````Cond1 or Cond2 or Cond3 or Cond4 or Cond5 or Cond6
``````

Therefore, a sufficient condition for Overlap is the opposite (De Morgan)

``````Not Cond1 AND Not Cond2 And Not Cond3 And Not Cond4 And Not Cond5 And Not Cond6
``````
• what do you mean by edges?, maybe faces? Feb 16, 2011 at 0:56
• Does your algorithm assume that the cubes are axis-aligned? Sry for bothering you^^ Feb 16, 2011 at 2:58
• @Dave, it does. As did the answers to the previous question. If that assumption is wrong, the problem becomes more complex to solve. Feb 16, 2011 at 4:39
• this is still not fixed, ridiculous Dec 10, 2016 at 9:39
• @Istrebitel I finally fixed it for you, thanks to adventofcode.com/2021/day/22 :) Dec 22, 2021 at 15:16

Cubes are made up of 6 rectangular (okay, square) faces.

Two cubes do not intersect if the following conditions are met.

• None of the faces of 2 cubes intersect.
• One cube does not completely contain the other.

The post you linked can be easily extended. Just add Z.

• +1 easily implemented if you already have code that tests case 1 Feb 16, 2011 at 2:59
• Just a side note...cube A completely contains cube B if cube A contains any vertex of cube B. You need only check one vertex of each cube for containment in the other cube; if the cube faces don't intersect, then either none of the vertices will be contained, or they all will be. Feb 16, 2011 at 22:09

I suppose (did not think much, maybe my condition is not enough) check if all the vertices of first cube are out of the second and inverse: all vertices of second are out of the first.

To check if the vertex is in the cube or not, transform it's coordinates to cube-related coordinate system (apply translation to the cube center and cube rotation). Then simply check each coord (x, y, z) is smaller then half a side

• That condition is not enough, because all the vertices of each cube can be out of the other and yet they still intersect (for example, if cube A is a slightly-rotated copy of cube B, you should be able to arrange them so that the above condition is true but they still intersect). Feb 16, 2011 at 22:07

This is just the accepted answer rewritten with the correction. It tests to see if the two axis aligned cuboids have any segment of the X,Y, and Z axis in common, if they dont then it is impossible for them to have a collision. The function assumes there is a collision and performs the tests to check if there isnt.

``````Function func_Intersect(ByVal cuboid1_MinX As Double, ByVal cuboid1_MaxX As Double, ByVal cuboid1_MinY As Double, ByVal cuboid1_MaxY As Double, ByVal cuboid1_MinZ As Double, ByVal cuboid1_MaxZ As Double, ByVal cuboid2_MinX As Double, ByVal cuboid2_MaxX As Double, ByVal cuboid2_MinY As Double, ByVal cuboid2_MaxY As Double, ByVal cuboid2_MinZ As Double, ByVal cuboid2_MaxZ As Double) As Boolean
func_Intersect = True
If cuboid1_MaxX < cuboid2_MinX Then
func_Intersect = False
ElseIf cuboid2_MaxX < cuboid1_MinX Then
func_Intersect = False
ElseIf cuboid1_MaxY < cuboid2_MinY Then
func_Intersect = False
ElseIf cuboid2_MaxY < cuboid1_MinY Then
func_Intersect = False
ElseIf cuboid1_MaxZ < cuboid2_MinZ Then
func_Intersect = False
ElseIf cuboid2_MaxZ < cuboid1_MinZ Then
func_Intersect = False
End If
End Function
``````