The best way to express this sort of iterative procedure in Haskell is as an *infinite list* of each successive result. Piecing together your four steps yields a notion of a function from a solution to a different (better) solution; all you need to do is apply this infinitely many times. The user of your function can then use any list function to get the answer: `solve s0 !! numIterations`

, or `find stoppingCondition $ solve s0`

, or whatever you want.

In order to get here, let's write out the types for each of these functions.

`moves :: Solution -> [Move]`

Given a possible solution, figure out the possible changes you can make.
`value :: Solution -> Move -> Double`

Given a solution and a move, evaluate it and record that value as some real number.
`choose :: Solution -> [Move] -> Move`

Given a solution and a list of moves, pick the best one.
`apply :: Solution -> Move -> Solution`

Given a move, apply it to an existing solution to get a new one.

You want to write a function with a type something like `solve :: Solution -> (Solution -> Bool) -> Solution`

which takes an initial solution and a stopping condition to execute your algorithm.

Instead, let's make this an infinite list; this means that you'll just remove the predicate and have `Solution -> [Solution]`

.

```
import Data.Ord
import Data.List
-- moves, value, and apply are domain-specific
choose :: Solution -> [Move] -> Move
choose s ms = maximumBy (comparing $ value s) ms
solve :: Solution -> [Solution]
solve = iterate $ \s -> apply s . choose s $ moves s
```

Here, the key is `iterate :: (a -> a) -> a -> [a]`

, which repeatedly applies a function to a value and gives you the results—exactly the description of your algorithm.

However, the way I'd really write this would be the following:

```
import Data.Ord
import Data.List
solve :: Ord o => (s -> [m]) -> (s -> m -> o) -> (s -> m -> s) -> s -> [s]
solve moves value apply = iterate step
where step s = apply s . choose s $ moves s
choose s = maximumBy (comparing $ value s)
```

The advantage of this is that you can reuse this same generic structure for *any* problem domain. All you need to do is to provide the `moves`

, `value`

, and `apply`

functions! And depending on my mood, I might rewrite that as this:

```
import Control.Applicative
import Data.Ord
import Data.List
solve :: Ord o => (s -> [m]) -> (s -> m -> o) -> (s -> m -> s) -> s -> [s]
solve moves value apply = iterate step
where step = (.) <$> apply <*> choose <*> moves
choose = maximumBy . comparing . value
```

Here, we use applicative notation to say that we're effectively just doing `(.) apply choose moves`

(which is just `apply . choose $ moves`

) in a context where each of those functions is implicitly passed a parameter `s`

(the reader applicative). If we really wanted to tersify things, we could write

```
import Control.Applicative
import Data.Ord
import Data.List
solve :: Ord o => (s -> [m]) -> (s -> m -> o) -> (s -> m -> s) -> s -> [s]
solve moves value apply =
iterate $ (.) <$> apply <*> maximumBy . comparing . value <*> moves
```

Any of these snippets will do exactly what you need. (Proviso: there are no effects/monads in any of your functions, so randomness is out. You make this monadic easily, though.)

Just for kicks, though, let's think about the `State`

monad. This represents a computation with some sort of environment, so that `State s a`

is isomorphic to `s -> (a,s)`

—something which can see the state and potentially update it. Here, all the `Solution ->`

s on the left of your function signatures would disappear, as would the `-> Solution`

s on the right. That would leave you with

`moves :: State Solution [Move]`

`value :: Move -> State Solution Double`

`choose :: [Move] -> State Solution Move`

`apply :: Move -> State Solution ()`

This means that you would have some monadic action `step`

:

```
import Control.Applicative
import Control.Monad.State
import Data.Ord
import Data.List
choose :: [Move] -> State Solution Move
choose = let val m = do v <- value m
return (m,v)
in fst . maximumBy (comparing snd) <$> mapM val ms
step :: State Solution ()
step = apply =<< choose =<< moves
```

You could make this more point-free, or make it polymorphic just as above, but I won't do that here. The point is that once you have `step`

, you can generate answers with `runState . last $ replicateM_ numIterations step`

, or given a `whileM`

function, `runState $ whileM (stoppingCondition :: State Solution Bool) step`

. Again, the user can decide how to stop it. Your `moves`

and `value`

functions would probably query the state with `get :: State s s`

; `apply`

would probably use `modify :: (s -> s) -> State s ()`

to tweak the state without needing to pull it back out. You can see the similarity with the structure from above in these types; and in fact, you can see that structure in the definition of `step`

, as well. Each one says "string together `apply`

, `choose`

/`value`

, and `moves`

", which is the definition of your algorithm.

The take-home message from both of these is that you want to avoid explicit loops/recursion, as you so rightly realized. If you think about this algorithm imperatively, then the `State`

monad seems like a natural structure, as it hides exactly those imperative features you were thinking of. However, it has downsides: for instance, everything has become monadic, and—worst of all—functions other than `apply`

are able to change the saved solution. If you instead imagine this algorithm as producing a *new* result each time, you get the notion of `step :: Solution -> Solution`

, and from there you can use `iterate`

to get a well-behaved infinite list.