I am writing a program in C# 4.0 that I've abstracted to the following (I mention the language so that you know what libraries I have to work with; no third-party libraries):

Let `S = { s1, s2, s3, ..., sn }`

.

For all `si`

, `sj`

in `S`

, `i != j`

, function `f(si, sj)`

is an element of `{ true, false }`

. Calling this function `f`

is quite expensive and should be done as few times as possible, however.

Given set `T = { t1, t2, t3, ..., tm }`

a non-empty subset of `S`

, compute a sequence `U = u1, u2, u3, ..., uo`

which contains all the elements of `T`

such that `f(ui, uj) == false`

for all `i < j`

, and `f(ui, s') == false`

for all `i`

and `s'`

in `S - U`

. You may assume such a sequence exists.

Although this is in no way related to school (it's for work), I'd *prefer* the least amount of help to get me to the most optimal solution you can think of, so that I can learn more :)

Hints (some stuff I've thought about:)

**You need to visit each node at least once.**Consider the case of`T = { t }`

and`f(t, s') == false`

for all`s'`

in`S - T`

and`|S| >= 2`

. Once, in this case, is also sufficient.Minimally

`U`

must be computed. This computation can be represented by the following: An`|S|x|S|`

adjacency matrix with entries of`?`

: I don't know`1`

: Depends on.`0`

: Does not depend on.`-`

: I don't care.

Consider this (I'm walking myself through an example to see if there's a pattern to the optimal potential check sequences to help develop an algorithm). `S = { a, b, c, d, e }`

`T = { a, b, c }`

(signified by the stars):

```
a b c d e
----------------
*a | - - - ? ?
*b | - - - ? ?
*c | - - - ? ?
d | - - - - ?
e | - - - ? -
```

`U = { a, b, c }`

initially. The diagonals are `-`

because `f`

is not defined when its operands are equal. Since `a`

, `b`

and `c`

are already in the set, it doesn't matter if anyone depends on them, hence `-`

.

`f(a, d)`

, `f(a, e)`

, `f(b, d)`

, `f(b, e)`

, `f(c, d)`

, `f(c, e)`

are all equal candidates due to the symmetries. Suppose we choose `f(a, d)`

and it returns false. Our table now looks like this:

```
a b c d e
----------------
*a | - - - 0 ?
*b | - - - ? ?
*c | - - - ? ?
d | - - - - ?
e | - - - ? -
```

Case 1: `U = { a, b, c }`

To find this out, we could do it in 3 checks, if we got lucky, by checking the `f(b, d)`

, `f(c, d)`

and `f(e, d)`

and having them all be `false`

.

Case 2: `U = { a, b, c, d, e }`

To find this out, we could do it in 2 checks, if we got lucky, by checking `f(b, d)`

and `f(a, e)`

and having them both return `true`

.

*(I haven't thought these through, completely, yet, and I need to go eat. Thanks to everyone reading!)*

Case 3: `U = { a, b, c, d }`

Case 4: `U = { a, b, c, e }`

`U`

not depending on any elements of`S`

that aren't in`U`

, since that seems to have been lost in your rephrase. Also, a question: is`f`

transitive? – Dougal Aug 16 '12 at 21:48`f`

; at a minimum, you'll need to check`f`

from each node in`U`

to each node in`S - U`

(`o (n-o)`

checks), and probably also each element in`U`

to its successors (`o (o-1) / 2`

checks), for an`on - o^2/2 - o/2`

lower bound. – Dougal Aug 16 '12 at 22:20