I started toying with this idea some years ago when I wrote my university papers. The idea is this - the **perfect** color quantization algorithm would take an arbitrary true-color picture and reduce the number of colors to the minimum possible, while maintaining that the new image is completely indistinguishable from the original with a naked eye.

Basically the setting is simple - you have a set of points in the RGB cube (from 0 to 255 integer values on each axis). You have to replace each of these points with another point in such a way that:

- The total number of points after the operation is as small as possible;
- The distance from an original point to the replaced point is no larger than some predefined constants R, G and B on each of the red, green and blue axis (these are taken from the sensitivity of the human eye and are in general configurable by the user).

I know that there are many color quantization algorithms out there that work with different efficiencies, but they are mostly targeted at reducing colors to a certain number, not "the minimum possible without violating these constraints".

Also, I would like the algorithm to produce really **absolute minimum** possible, not just something that is "pretty close to minimum".

Is this possible without a time consuming full search of all combinations (infeasible for any real picture)? My instincts tell me that this is a NP-complete problem or worse, but I cannot prove it.

**Bonus setting:** Change the limit from constants R,G,B to a function F(R_{source}, G_{source}, B_{source}, R_{target}, G_{target}, B_{target}) which returns TRUE if the mapping would be OK, and FALSE if it was out of range.