I want to complement J. Abrahamson's answer by answering your other question about why the decoder is not a `Pipe`

.

The difference between a `Pipe`

with a type like:

```
pipe :: Pipe a b m r
```

... and function between `Producer`

s like (I call these "getter"s):

```
getter :: Producer a m r -> Producer b m r
```

... is that a `Pipe`

can be used to transform `Producer`

s, `Consumer`

s, and other `Pipe`

s:

```
(>-> pipe) :: Producer a m r -> Producer b m r
(>-> pipe) :: Pipe x a m r -> Pipe x b m r
(pipe >->) :: Consumer b m r -> Consumer a m r
(pipe >->) :: Pipe b y m r -> Pipe a y m r
```

... whereas a "getter" can only transform `Producer`

s. Some things cannot be modeled correctly using `Pipe`

s and leftovers are one of those things.

`conduit`

purports to model leftovers using `Conduit`

s (the `conduit`

analog of `Pipe`

s) but it gets this wrong. I've put together a simple example showing why. First, just implement a `peek`

function for `conduit`

:

```
import Control.Monad.Trans.Class (lift)
import Data.Conduit
import Data.Conduit.List (isolate, sourceList)
peek :: Monad m => Sink a m (Maybe a)
peek = do
ma <- await
case ma of
Nothing -> return ()
Just a -> leftover a
return ma
```

This works as expected for simple cases like this:

```
source :: Monad m => Source m Int
source = sourceList [1, 2]
sink1 :: Show a => Sink a IO ()
sink1 = do
ma1 <- peek
ma2 <- peek
lift $ print (ma1, ma2)
```

This will return the first element of the source twice:

```
>>> source $$ sink1
(Just 1,Just 1)
```

... but if you compose a `Conduit`

upstream of a `Sink`

, any leftovers that the sink pushes back are irreversibly lost:

```
sink2 :: Show a => Sink a IO ()
sink2 = do
ma1 <- isolate 10 =$ peek
ma2 <- peek
lift $ print (ma1, ma2)
```

Now the second `peek`

incorrectly returns `2`

:

```
>>> source $$ sink2
(Just 1,Just 2)
```

Also, note that `pipes-parse`

just got a new major version released today, which simplifies the API and adds an extensive tutorial that you can read here.

This new API correctly propagates leftovers further upstream. Here is the analogous example for `pipes`

:

```
import Lens.Family.State.Strict (zoom)
import Pipes
import Pipes.Parse
import Prelude hiding (splitAt)
parser :: Show a => Parser a IO ()
parser = do
ma1 <- zoom (splitAt 10) peek
ma2 <- peek
lift $ print (ma1, ma2)
producer :: Monad m => Producer Int m ()
producer = each [1, 2]
```

Even though the first `peek`

is also limited to the first 10 values, it correctly undraws the first value and makes it available to the second `peek`

:

```
>>> evalStateT parser producer
(Just 1,Just 1)
```

Conceptually, the reason why `pipes-parse`

"thinks in terms of `Producer`

s" is because otherwise the concept of leftovers is not clearly defined. If you don't clearly define what your source is, you can't clearly articulate where leftovers values should go. This is why `Pipe`

s and `Consumer`

s do not lend themselves well to tasks that require leftovers.