I consider it a half-truth. Haskell has an amazing ability to abstract, and that includes abstraction over imperative ideas. For example, Haskell has no built-in imperative while loop, but we can just write it and now it does:
while :: (Monad m) => m Bool -> m () -> m ()
while cond action = do
c <- cond
then action >> while cond action
else return ()
This level of abstraction is difficult for many imperative languages. This can be done in imperative languages that have closures; eg. Python and C#.
But Haskell also has the (highly unique) ability to characterize allowed side-effects, using the Monad classes. For example, if we have a function:
foo :: (MonadWriter [String] m) => m Int
This can be an "imperative" function, but we know that it can only do two things:
- "Output" a stream of strings
- return an Int
It can't print to the console or establish network connections, etc. Combined with the abstraction ability, you can write functions which act on "any computation that produces a stream", etc.
It's really all about Haskell's abstraction abilities that makes it a very fine imperative language.
However, the false half is the syntax. I find Haskell pretty verbose and awkward to use in an imperative style. Here is an example imperative-style computation using the above
while loop, which finds the last element of a linked list:
lastElt :: [a] -> IO a
lastElt  = fail "Empty list!!"
lastElt xs = do
lst <- newIORef xs
ret <- newIORef (head xs)
while (not . null <$> readIORef lst) $ do
(x:xs) <- readIORef lst
writeIORef lst xs
writeIORef ret x
All that IORef garbage, the double read, having to bind the result of a read, fmapping (
<$>) to operate on the result of an inline computation... it's all just very complicated looking. It makes a whole lot of sense from a functional perspective, but imperative languages tend to sweep most of these details under the rug to make them easier to use.
Admittedly, perhaps if we used a different
while-style combinator it would be cleaner. But if you take that philosophy far enough (using a rich set of combinators to express yourself clearly), then you arrive at functional programming again. Imperative-style Haskell just doesn't "flow" like a well-designed imperative language, e.g. python.
In conclusion, with a syntactic face-lift, Haskell might well be the best imperative language. But, by the nature of face lifts, it would be replacing something internally beautiful and real with something externally beautiful and fake.
lastElt with this python transliteration:
assert xs, "Empty list!!"
lst = xs
ret = xs.head
ret = lst.head
lst = lst.tail
Same number of lines, but each line has quite a bit less noise.
For what it's worth, this is how a pure replacement in Haskell looks like:
lastElt = return . last
That's it. Or, if you forbid me from using
lastElt  = fail "Unsafe lastElt called on empty list"
lastElt [x] = return x
lastElt (_:xs) = lastElt xs
Or, if you want it to work on any
Foldable data structure and recognize that you don't actually need
IO to handle errors:
import Data.Foldable (Foldable, foldMap)
import Data.Monoid (Monoid(..), Last(..))
lastElt :: (Foldable t) => t a -> Maybe a
lastElt = getLast . foldMap (Last . Just)
Map, for example:
λ➔ let example = fromList [(10, "spam"), (50, "eggs"), (20, "ham")] :: Map Int String
λ➔ lastElt example
(.) operator is function composition.