The fastest way to do it (with the least possible average number of comparisons equal to the theoretical value) is:

```
c1 -→ o | 3/10 comparisons
c2 -→ o
o -→ o
```

Then after comparison of two bigger numbers (c1 and c2) we have

```
o -→ c1
o -→ o -→ c2 | 4/10 comparisons
↘
↘o
```

Then we compare "c1" to "c2" and get two possible variants (first if c1 > c2, otherwise second one)

```
A)Worse(26/45 of all cases) B)Better(19/45) | 5/10 comparisons
o -→ c1 -↘ b-↘
↘ ↘
o -→ c2 -→ o o -→ c1-→ c2-→ c3
↘ ↘
↘o ↘a
```

A) In the first case our next step will be comparison of "c1" to "c2" after what we can get A1) if c1>c2 otherwise A2)

```
A1) A2) | 6/10
o↘ c1-→ c2 -→ o -→ o
↘ ↗
o -→ c1-→ c2 -→ c3 a -→ b
↘
↘a
```

A1) We sort "a" in sequence {c1;c2;c3} starting with comparison to c2, then we get

```
A1.1) A1.2) | 8/10
a↘ a↘
↘ ↘
c1-→ c2-→ o -→ o -→ o c1-→ c2-→ c3-→ o -→ o
```

A1)Then we have only to sort "a" in sequence {c1;c2} or {c1;c2;c3} starting in both(!) A1.1 and A1.2 cases with comparison to "c2" in 1-2 (A1) or 2 (A2) comparisons.

A2) We sort "a" in {c1;c2} always starting with comparison to c1, then we sort "b" in a sequence of elements which are smaller then "a" starting with comparing to any element(if there are 2) , 2nd (if there are 3), any of 2nd or 3rd(if there 4 elements in that sequence)

B) The same way as above we sort "a" in a sequence {c1;c2;c3} starting with comparison to c2, after that we sort "b" in a sequence of elements smaller than c3 starting with comparison to c2(if there are 3 elements) or to c2 or c3 (if there are 4). This will take 3-4 comparisons. You can also do vice versa starting with "b", the result won't change.

In total, this algorithm sorts 6 numbers in 9 comparisons in 19/45 cases and
in 10 comparisons in 26/45 cases.

### Minute of theory

6!=720, 2^9=512, that means after 9 comparisons we can have 512 different results, so for 304 (304 is 512 - 2*(720-512)) of them we can say "that's all, we definitely know the order", but for the 208 rest we need one more comparison to distinct them from 208 another disposals with the same comparison results.
304/720 = 19/45; 208*2 / 720 = 26/45 ~ 0.578
So the best possible algorithm will have 9.578 comparisons on average.
There is another option: sort 5 in 7 comparisons and sort 6th element in 3 comparisons afterwards, but since "5 in 7" best algorithm is sorting in 6 comparisons in 1/15 of cases, "6 in 10" algorithm will sort in 8 comparison in 1/45 cases (9 comparisons in 16/45 cases, 10 comparisons in 28/45 cases) leading to 9.6 comparisons on average.

`6! = 720, 2 ** 10 = 1024`

) – Niet the Dark Absol Nov 28 '10 at 9:27