The problem sounds like this: we get n-cubes. Each cube has a length (the edge's length) and a colour. The edges' lengths are distinct, but the culours are not, for instance: any two cubes can never have the same length, but it is possible to have the same colour. The colours are from 1 to p (p is given).

We have to build a cube-tower that has a maximum height, following these rules:

1) a cube cannot be placed upon a cube if they have the same colour;

2) a cube cannot pe placed upon a cube whose edge's length is smaller.

e.g: cube c1 has a length of 3, cube c2 has a length of 5. cube c1 can be placed on the top of c2, but cube c2 cannot be placed on the top of c1.

Alright, so the algorithm I came up with in order to solve this problem is this:

- we sort the cubes by edge length, in descending order and we put them in an array;
- we add the first cube in the array to the Tower;
- we save the length of the last inserted cube( in this case, the first cube's length ) in variable l;
- we save the colour of the last inserted cube( in this case, the first cube's colour ) in variable c;
- we go through the rest of the array, inserting the first cube whose length is smaller than l and colour different than c and then we repeat 3-4-5;

Now what I'm having difficulties with is, how do I prove this greedy algorithm to be the optimal one? I guess that the proof has to somehow look like the ones here: http://www.cs.princeton.edu/~wayne/kleinberg-tardos/pdf/04GreedyAlgorithmsI-2x2.pdf

"whose length is smaller than l "in step 5 is really not necessary as that will always be the case for all subsequent cubes.