My best shot so far:

A delivery vehicle needs to make a series of deliveries (d

_{1},d_{2},...d_{n}), and can do so in any order--in other words, all the possible permutations of the set D = {d_{1},d_{2},...d_{n}} are valid solutions--but the particular solution needs to be determined before it leaves the base station at one end of the route (imagine that the packages need to be loaded in the vehicle LIFO, for example).Further, the cost of the various permutations is not the same. It can be computed as the sum of the squares of distance traveled between d

_{i -1}and d_{i}, where d_{0}is taken to be the base station, with the caveat that any segment that involves a change of direction costs 3 times as much (imagine this is going on on a railroad or a pneumatic tube, and backing up disrupts other traffic).Given the set of deliveries

`D`

represented as their distance from the base station (so`abs(d`

_{i}`-d`

_{j}`)`

is the distance between two deliveries) and an iterator`permutations(D)`

which will produce each permutation in succession, find a permutation which has a cost less than or equal to that of any other permutation.

Now, a direct implementation from this description might lead to code like this:

```
function Cost(D) ...
function Best_order(D)
for D1 in permutations(D)
Found = true
for D2 in permutations(D)
Found = false if cost(D2) > cost(D1)
return D1 if Found
```

Which is O(n*n!^2), e.g. pretty awful--especially compared to the O(n log(n)) someone with insight would find, by simply sorting D.

My question: can you come up with a plausible problem description which would naturally lead the unwary into a *worse* (or differently awful) implementation of a sorting algorithm?

worsequesiton :-D – Paul Dixon Mar 13 '09 at 16:47