The solution explained by them is to always hold only the items that are correctly sorted. If you do this for three unsorted elements, then after first try, there's 1/6 chance that you sort all of them (i.e. we're finished after one hit), 3/6 chance that you sort one of the items (and you need 2 more hits on average) and 2/6 chance that none will be sorted (and you still need the same count of hist as when you started). This gives you a simple recurrent formula, which after evaluating gives that, on average, you need 3 hits to sort 3 unsorted items.

The fact that your strategy gives the wrong result just means that it's not the best strategy.

Their solution is not the only one that gives the same results, though, just the simplest. Another possible way is to hold all sorted items (if there are any), plus some of the unsorted. But with the condition that all of the items you are not holding have to be able to get to their correct positions without you letting go of the items you're holding (or in other words, they have to form cycle(s) in the permutation).

Consider the following example:

```
1 3 2 5 6 4
```

There is 5 unsorted items, so Google's solution will take on average 5 hits.

The `1`

is sorted, so we have to hold it. If we hold `5`

, `6`

and `4`

too, the remaining items (`3`

and `2`

) can get to their correct position. When we do it, they will get there in 2 hits, on average. Now we have 3 unsorted items and we can sort them, on average, in 3 hits. (We have to keep all of them free, because they form one cycle.) So this approach, while more complicated, is as fast as the original one.

Whythis strategy works is shown with the proof (which I cannot explain to you, I have to spent some more time with it myself ;)) – Felix Kling May 8 '11 at 16:39