How good is 'pure' functional
programming for basic routine
implementations, e.g. list sorting,
string matching etc.?

Very. I'll do your problems in Haskell, and I'll be slightly verbose about it. My aim is not to convince you that the problem can be done in 5 characters (it probably can in J!), but rather to give you an idea of the constructs.

```
import Data.List -- for `sort`
stdlistsorter :: (Ord a) => [a] -> [a]
stdlistsorter list = sort list
```

Sorting a list using the `sort`

function from `Data.List`

```
import Data.List -- for `delete`
selectionsort :: (Ord a) => [a] -> [a]
selectionsort [] = []
selectionsort list = minimum list : (selectionsort . delete (minimum list) $ list)
```

Selection sort implementation.

```
quicksort :: (Ord a) => [a] -> [a]
quicksort [] = []
quicksort (x:xs) =
let smallerSorted = quicksort [a | a <- xs, a <= x]
biggerSorted = quicksort [a | a <- xs, a > x]
in smallerSorted ++ [x] ++ biggerSorted
```

Quick sort implementation.

```
import Data.List -- for `isInfixOf`
stdstringmatch :: (Eq a) => [a] -> [a] -> Bool
stdstringmatch list1 list2 = list1 `isInfixOf` list2
```

String matching using `isInfixOf`

function from `Data.list`

It's common to implement such basic
functions within the base interpreter
of any functional language, which
means that they will be written in an
imperative language (c/c++). Although
there are many exceptions..

Depends. Some functions are more naturally expressed imperatively. However, I hope I have convinced you that some algorithms are also expressed naturally in a functional way.

At least, I wish to ask: How difficult
is it to emulate imperative style
while coding in 'pure' functional
language?

It depends on how hard you find Monads in Haskell. Personally, I find it quite difficult to grasp.