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.

5 Answers 5


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.

Credit: https://silentmatt.com/rectangle-intersection/


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?
    – Dave O.
    Feb 16, 2011 at 0:56
  • Does your algorithm assume that the cubes are axis-aligned? Sry for bothering you^^
    – Dave O.
    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.
    – btilly
    Feb 16, 2011 at 4:39
  • 1
    this is still not fixed, ridiculous
    – Istrebitel
    Dec 10, 2016 at 9:39
  • 4
    @Istrebitel I finally fixed it for you, thanks to adventofcode.com/2021/day/22 :)
    – Thorarin
    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
    – Dave O.
    Feb 16, 2011 at 2:59
  • 2
    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.
    – jprete
    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

  • 1
    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).
    – jprete
    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

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