A one-liner:

```
import Control.Monad.Reader
-- sample data
rulesetL = [ (== 1), (>= 2), (<= 3) ]
list = [1..10]
result = and $ concatMap (sequence rulesetL) list
```

(The type we're working on here is `Integer`

, but it could be anything else.)

Let me explain what's happening: `rulesetL`

is of type `[Integer -> Bool]`

. By realizing that `(->) e`

is a monad, we can use

```
sequence :: Monad m => [m a] -> m [a]
```

which in our case will get specialized to type `[Integer -> Bool] -> (Integer -> [Bool])`

. So

```
sequence rulesetL :: Integer -> [Bool]
```

will pass a value to all the rules in the list. Next, we use `concatMap`

to apply this function to `list`

and collect all results into a single list. Finally, calling

```
and :: [Bool] -> Bool
```

will check that all combinations returned `True`

.

**Edit:** Check out *dave4420*'s answer, it's nicer and more concise. Mine answer could help if you'd need to combine rules and apply them later on some lists. In particular

```
liftM and . sequence :: [a -> Bool] -> (a -> Bool)
```

combines several rules into one. You can also extend it to other similar combinators like using `or`

etc. Realizing that rules are values of `(->) a`

monad can give you other useful combinators, such as:

```
andRules = liftM2 (&&) :: (a -> Bool) -> (a -> Bool) -> (a -> Bool)
orRules = liftM2 (||) :: (a -> Bool) -> (a -> Bool) -> (a -> Bool)
notRule = liftM not :: (a -> Bool) -> (a -> Bool)
-- or just (not .)
```

etc. (don't forget to import `Control.Monad.Reader`

).