Almost everything you can do with monads you can do without them. (Well, some are special like `ST`

, `STM`

, `IO`

, etc., but that's a different story.) But:

- they allow you to encapsulate many common patterns, like in this case stateful computations, and hide details or boiler-plate code that would be otherwise needed; and
- there are plethora of functions that work on any (or many) monads, which you can just specialize for a particular monad you're using.

To give an example: Often one needs to have some kind of a generator that supplies unique names, like when generating code etc. This can be easily accomplished using the state monad: Each time `newName`

is called, it outputs a new name and increments the internal state:

```
import Control.Monad.State
import Data.Tree
import qualified Data.Traversable as T
type NameGen = State Int
newName :: NameGen String
newName = state $ \i -> ("x" ++ show i, i + 1)
```

Now let's say we have a tree that has some missing values. We'd like to supply them with such generated names. Fortunately, there is a generic function `mapM`

that allows to traverse any traversable structure with any monad (without the monad abstraction, we wouldn't have this function). Now fixing the tree is easy. For each value we check if it's filled (then we just use `return`

to lift it into the monad), and if not, supply a new name:

```
fillTree :: Tree (Maybe String) -> NameGen (Tree String)
fillTree = T.mapM (maybe newName return)
```

Just imagine implementing this function without monads, with explicit state - going manually through the tree and carrying the state around. The original idea would be completely lost in boilerplate code. Moreover, the function would be very specific to `Tree`

and `NameGen`

.

But with monads, we can go even further. We could parametrize the name generator and construct even more generic function:

```
fillTreeM :: (Monad m) => m String -> Tree (Maybe String) -> m (Tree String)
fillTreeM gen = T.mapM (maybe gen return)
```

Note the first parameter `m String`

. It's not a constant `String`

value, it's a recipe for generating a new `String`

within `m`

, whenever it's needed.

Then the original one can be rewritten just as

```
fillTree' :: Tree (Maybe String) -> NameGen (Tree String)
fillTree' = fillTreeM newName
```

But now we can use the same function for many very different purposes. For example, use the `Rand`

monad and supply randomly generated names.

Or, at some point we might consider a tree without filled out nodes invalid. Then we just say that wherever we're asked for a new name, we instead abort the whole computation. This can be implemented just as

```
checkTree :: Tree (Maybe String) -> Maybe (Tree String)
checkTree = fillTreeM Nothing
```

where `Nothing`

here is of type `Maybe String`

, which, instead of trying to generate a new name, aborts the computation within the `Maybe`

monad.

This level of abstraction would be hardly possible without having the concept of monads.

`Reader`

will be trivial. It's exactly the same thing as just passing an argument. It doesn't even get returned!`ReaderT`

, on the other hand, is a bit more useful. – Carl Jul 4 at 16:33