This question is an extension to the following one. The difference is that now our function to optimize will have higher order relations between elements:

We have an array of elements `a1,a2,...aN`

from an alphabet `E`

. Assuming `|N| >> |E|`

.

For each symbol of the alphabet we define an unique integer priority = `V(sym)`

. Let's define `V{i} := V(symbol(ai))`

for the simplicity.

The task is to find a priority function V for which:

```
Count(i)->MIN | V{i} > V{i+1} <= V{i+2}
```

In other words, I need to find the priorities / permutation of the alphabet for which the number of positions `i`

, satisfying the condition `V{i}>V{i+1}<=V{i+2}`

, is minimum.

**Maximum required abstraction (low priority for me)**. I guess once the solution model for the initial question is extended to cover the first part of this one, extending it farther (see below) will be easier.

Given a matrix of signs B of size MxK (basically `B[i,j]`

is from the set `{<,>,<=,>=}`

), find the priority function V for which:

```
Sum(for all j in range [1,M]) {Count(i)}->EXTREMUM | V{i} B[j,1] V{i+1} B[j,2] ... B[j,K] V{i+K}
```

As an example, find the priority function `V`

, for which the number of `i`

, satisfying `V{i}<V{i+1}<V{i+2}`

or `V{i}>V{i+1}>V{i+2}`

, is minimum.

`S{i}>S{i+1}<=S{s+2}`

. Now I'm trying to reorder the alphabet in a most effective way to reduce the amount of sub-strings that need to be sorted directly, greatly increasing performance. I've also developed a generalization of Itoh-Tanaka methods for higher orders, that is why the second part of the question exists. So, well, there is a pretty strong motivation behind this :) – kvark Feb 13 '11 at 14:59