# The math to render a cube?

My friend and I are making a 3d rendering engine from scratch in our VB class at school, but I am not sure how the math to form the cube would work. Given six variables:

``````    rotX
rotY
rotZ
lenX
lenY
lenZ
``````

Which represent the rotation on x,y,z and the length on x,y,z respectively, what would be the formulas to make the cube? I know that all I have to do is calculate three segments and from those segments just create three parallelograms, so I just need the math to find what the three segments are. Thanks!

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Depends on how you're doing the rendering. OpenGL performs rotations by multiplying the current matrix with a particular matrix, whose formula is listed here. –  Kevin Oct 28 '13 at 20:08
To render, I'm just using the e.Graphics.DrawPolygon function to draw each of the 3 parallelograms derived from the 3 segments where the visible faces intersect. –  Mathew Kirschbaum Oct 28 '13 at 20:18
By "rendering", I mean, taking a three dimensional point and determining the two dimensional coordinates where that point would be drawn on your screen. Like, if I wanted to plot the point (16,23,42), where would your engine draw the pixel? Have you written the code for that yet? –  Kevin Oct 29 '13 at 11:59
No, that's actually what I need help on, now that I think of it. I could probably code the formulas to do the 3d rotation of the cube once I find a formula that actually helps me, but what I am not sure about is how to plot a 3d point onto a 2d surface. –  Mathew Kirschbaum Oct 29 '13 at 23:04

there are 2 basic 3D object representations for both are your data is insufficient.

1. surface representation

• objects are set of surface polygons/vertexes/...
• for cube its a set of 8 points + the triangles/quads for 6 faces
2. analytical representation

• objects are set of equations describing the object
• for cube its a intersection of 6 planes

I think you are using option 1 so what you need is: - position - orientation - size

usually an axis aligned cube looks like this:

``````const double a=1.0; //cube size;
double  pnt[8][3]=  //cube points
{
+a,-a,+a,
+a,+a,+a,
-a,+a,+a,
-a,-a,+a,
+a,-a,-a,
+a,+a,-a,
-a,+a,-a,
-a,-a,-a
};
int     tab[24]=
{
5,6,2,1,
6,7,3,2,
7,4,0,3
};
``````

well for size and orientation you can apply transformation matrix
or directly recompute points by direction vectors

• so you need to remember position (point) and orientation (3 vectors) and size (scalar)
• all above can be stored in single transformation matrix 4x4
• but if you want the vectors then points will be like this:

P(+a,-a,+a) -> +a*I -a*J +a*K

• where I,J,K are the orientation vectors
• a is cube size
• P(+a,-a,+a) is original axis aligned point in table above

Option 2 is more tricky to implement and unless you really need it (ray-tracing renders) then forget about it.

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