# How to represent a Rubik's cube

I want to know how we can design a rubics cube in mathematica .Is it possible and how can we go with it. how can we decide the different separation of the smaller cubes on the 6 faces of the cube .

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You are asking how to define a data structure. Your choices is arbitrary, as long as the operations you define work correctly. For example you could represent a cube like:

``````newCube[] := {
{red, red, red, red, red, red, red, red, red},
{orange, orange, orange, orange, orange, orange, orange, orange, orange},
{yellow, yellow, yellow, yellow, yellow, yellow, yellow, yellow, yellow},
{green, green, green, green, green, green, green, green, green},
{indigo, indigo, indigo, indigo, indigo, indigo, indigo, indigo, indigo},
{purple, purple, purple, purple, purple, purple, purple, purple, purple}
}
``````

Then you can either define a twist (and optionally anti-twist) operation, one for each move (3 axes, 3 layers to twist per axis, 2 directions to twist; alternatively 6 axes, 3 layers to twist per axis), or two rotate operations and a twist, and assume you can compose these to generate effects like `inverseRotate[simpleTwist[rotate[cube], ...], ...]`.

To figure out the code you need, you have to have a map from your representation to the real object. Perhaps it would be better to demonstrate an example for a coin, which is either heads or tails:

``````newCoin[] := {heads}

``````

This can be more complicated if it's not easy to represent your object with basic data structures, like lists. You could even represent your cube with matrices like:

``````newCube[] := {
/red, red, red\  /orange, orange, orange\
|red, red, red|  |orange, orange, orange|
\red, red, red/, \orange, orange, orange/, ...
}
``````

But the way the matrices are stitched together can't easily be represented. So their ordering in the list is arbitrary.

If you are still confused, you can do this:

Give each slot in your representation an arbitrary number (worst-case, you label them 0 through 53, but you can be more elegant about it). Then with a real Rubik's cube, write those numbers on each face. Then when you do an operation, write down their new positions. This is called a permutation that that particular allowed move/twist induces on your semigroup data structure. As mentioned earlier, there are quite a few of these (18), and you have to write them all down. Then you can have something like:

``````newCube[] := {0,1,2, 3,4,5, 6,7,8, ...53}

permutations = {
{12,15,0, 3,4,5, 6,7,8, ...},  (*figure these out yourself*)
{. . . },
{. . . },
{. . . },
{. . . },
{. . . },
{. . . },
{. . . },
{. . . },
{. . . },
{. . . },
{. . . },
{. . . },
{. . . },
{. . . },
{. . . }
}

twistCube[cube_, moveNumber_] := Permute[
cube,
FindPermutation[permutations[[moveNumber]]]
]
``````

You can optimize this with computer science tricks like rather than calling FindPermutation each time, making `permutations = FindPermutation /@ {...}`

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