The problem is in `r`

. Given the following definition of `Reader`

monad:

```
instance Monad ((->) e) where
return = const
f >>= g = \x -> g (f x) x
```

We can simplify `r`

:

```
r = p1 >> p2
= (>>=) p1 (\_ -> p2)
= (\f g x -> g (f x) x) p1 (\_ -> p2)
= \x -> (\_ -> p2) (p1 x) x
= \x -> p2 x
```

This also shows that `Reader`

's `(>>)`

is just `const`

with a bit more specific type.

If you want to distribute the environment and then execute both actions, you have to bind the result of applying `p1`

to the environment, for example:

```
r = do a1 <- p1
a2 <- p2
return (a1 >> a2)
```

Or using `Applicative`

:

```
r = (>>) <$> p1 <*> p2
```

Expanding on the `Reader`

part, `Control.Monad.Reader`

provides three variants of `Reader`

.

- the implicit
`(->) e`

, which is what the function `r`

uses
- the monad transformer
`ReaderT e m`

, a newtype wrapper for functions of type `e -> m a`

- the explicit
`Reader e`

, defined in terms of `ReaderT`

as `ReaderT e Identity`

Without any further information, the implicit `(->) e`

will be used. Why?

The overall type of `do`

block is given by the last expression, which is also constrained to be of the form `Monad m => m a`

for some `m`

and `a`

.

Looking back at `r`

, it's clear that the `do`

block has a type `String -> IO ()`

as given by the type of `r`

and also `p2`

. It also requires `String -> IO ()`

to be `Monad m => m a`

. Now, unifying these two types:

```
m = (->) String
a = IO ()
```

This matches `(->) e`

monad instance by choosing `e = String`

.

Being a monad transformer, `ReaderT`

takes care of the inner plumbing to make sure the actions of the inner monad are properly sequenced and executed. To select `ReaderT`

, it is necessary to explicitly mention it (usually in a type signature, but functions which fix the type to be `ReaderT`

, such as `runReaderT`

, also work):

```
r :: ReaderT String IO ()
r = do ? p1
? p2
r' :: String -> IO ()
r' = runReaderT r
```

This comes with another problem, `p1`

and `p2`

have a type `String -> IO ()`

, which doesn't match the required `ReaderT String IO ()`

.

The ad-hoc solution (tailored exactly for this situation), is just to apply

```
ReaderT :: (e -> m a) -> ReaderT e m a
```

To obtain something more general, `MonadIO`

type class can lift `IO`

actions into the transformer and `MonadReader`

type class allows accessing the environment. These two type classes work as long as there is `IO`

(or `ReaderT`

respectively) somewhere in the transformer stack.

```
lift' :: (MonadIO m, MonadReader a m) => (a -> IO b) -> m b
lift' f = do
env <- ask -- get environment
let io = f env -- apply f to get the IO action
liftIO io -- lift IO action into transformer stack
```

Or more concisely:

```
lift' f = ask >>= liftIO . f
```

Regarding your question in comments, you can implement the relevant instances in this way:

```
newtype ReaderT e m a = ReaderT { runReaderT :: e -> m a }
instance Monad m => Monad (ReaderT e m) where
return = ReaderT . const . return
-- The transformers package defines it as "lift . return".
-- These two definitions are equivalent, though.
m >>= f = ReaderT $ \e -> do
a <- runReaderT m e
runReaderT (f a) e
instance Monad m => MonadReader e (ReaderT e m) where
ask = ReaderT return
local f m = ReaderT $ runReaderT m . f
reader f = ReaderT (return . f)
```

The actual typeclass can be found in the `mtl`

package (package, type class), the newtype and `Monad`

instance in `transformers`

package (package, type class).

As for making a `e -> m a`

`Monad`

instance, you are out of luck. `Monad`

requires a type constructor of kind `* -> *`

, which means we are attempting to do something like this (in pseudo-code):

```
instance Monad m => Monad (/\a -> e -> m a) where
-- ...
```

where `/\`

stands for type-level lambda. However, the closest thing we can get to a type level lambda is a type synonym (which must be fully applied before we can make type class instances, so no luck here) or a type family (which cannot be used as an argument to type class either). Using something like `(->) e . m`

leads to `newtype`

again.

`ReaderT r m`

instance for`r -> m a`

, but apparently there isn't. – ron Dec 14 '12 at 13:44`ReaderT`

is a type, not a class -- so there can't be instances of it! – Daniel Wagner Dec 14 '12 at 14:09`Monad`

instance for`(r -> m a)`

and then define a`MonadReader`

instance for that? – ron Dec 14 '12 at 17:41