I just wanted to comment on the difference between `Parsec s u (IO a)`

and `ParsecT s u IO a`

.

You correctly observed that trying to implement your function using `Parsec (IO a)`

yields to `Parser (IO (Parser (IO a))`

. Since both `Parser`

and `IO`

are monads, for both of them we have `join :: m (m a) -> m a`

, which allows to collapse double `Parser`

or double `IO`

. However, in our results we have `IO`

and `Parser`

interleaved. What we need is some function of type `IO (Parser a) -> Parser (IO a)`

. If we had such a function `f`

and some `x :: Parser (IO (Parser (IO a))`

, we could use it as `liftM f x :: Parser (Parser (IO (IO a)))`

and then use `join`

and `liftM join`

to collapse both parts into desired `Parser (IO a)`

.

Unfortunately there is no such general function for swapping two monads. It's not possible to construct such a function without knowing the internals of a monad, and for some monads it's not even possible at all. For example, there is no total function of type `(a -> Maybe b) -> Maybe (a -> b)`

(the first monad being `Maybe`

, the second one the reader monad `(->) a`

).

And this is why we have monad transformers. A monad transformer corresponding to some monad `M`

knows how to interleave `M`

with another monad. For some monads, such as `Reader`

, swapping it with another monad in the above manner is possible and its transformer is doing exactly that. `ReaderT r m a`

is defined as `r -> m a`

and we can construct:

```
import Control.Monad
import Control.Monad.Trans
import Control.Monad.Trans.Reader
swapReader :: (Monad m) => m (Reader r a) -> Reader r (m a)
swapReader = fromReaderT . join . lift . liftM (toReaderT . liftM return)
where
-- Helpers to convert ReaderT to Reader and back
fromReaderT :: (Monad m) => ReaderT r m a -> Reader r (m a)
fromReaderT = reader . runReaderT
toReaderT :: (Monad m) => Reader r (m a) -> ReaderT r m a
toReaderT = ReaderT . runReader
```

We convert `m (Reader r a)`

into `ReaderT r m (ReaderT r m a)`

by augmenting both the inner and outer part and then just collapse it using `join`

.

For other monads, such as `MaybeT`

, swapping is impossible (as in the example above with the `(->) a`

monad). So their transformers are defined differently, for example `MaybeT m a`

is defined as `m (Maybe a)`

, not `Maybe (m a)`

. Therefore `ReaderT r Maybe a`

is isomorphic `MaybeT (ReaderT r) a`

! There is just one sensible way how to combine `Reader`

and `Maybe`

and so both transformers result in the same thing.

Luckily, we don't have to care about this stuff, once somebody defines a transformer for us.
All we need to know is that the laws hold and how to run the transformer stack at the end.

**So using **`ParsecT s u IO a`

is the proper solution. `ParsecT`

knows how to interleave parsing within another monad and allows you to combine operations from both of them, without having to deal with the internals.

`conditionalParser :: (b -> Bool) -> Parser b -> Parser a -> Parser a -> Parser a`

(and similarly for the monadic version). This makes the combinator more versatile, its meaning is more obvious from its type, and also slightly less error prone. – Petr Pudlák Dec 27 '13 at 20:28