## Types

It sounds like you might be looking for the composition of functors, which lives in the transformers package in `Data.Functor.Compose`

:

```
newtype Compose f g a = Compose { getCompose :: f (g a) }
```

If I understand your two questions correctly, you want to add things before and after something else, and then parse the added data back out. We'll make a type for adding things before and after something else

```
data Surrounded a b c = Surrounded a c b
deriving (Functor)
surround :: a -> b -> c -> Surrounded a b c
surround a b c = Surrounded a c b
```

Now, supposing the data before something else is a `String`

and the data after something else is an `Int`

, you're looking for the type:

```
Free (Compose (Surrounded String Int) FooF) :: * -> *
```

## Instances

All that remains is to make `Serialize`

instances for `FooF x`

, `Surrounded a b c`

, `Compose f g x`

, and `Free f a`

. The first three of these are easy and can be derived by the cereal package:

```
deriving instance Generic (FooF x)
instance Serialize x => Serialize (FooF x)
deriving instance Generic (Surrounded a b c)
instance (Serialize a, Serialize b, Serialize c) => Serialize (Surrounded a b c)
deriving instance Generic (Compose f g a)
instance (Serialize (f (g a))) => Serialize (Compose f g a)
```

If we try to do the same for `Free`

, we would write `instance (Serialize a, Serialize (f (Free f a))) => Serialize (Free f a)`

. We'd run into `UndecidableInstances`

territory; to make a `Serialize`

instance for `Free`

, we first must have a `Serialize`

instance for `Free`

. We'd like to prove by induction that the instance already exists, but to do so, we'd need to be able to check that `f a`

has a `Serialize`

instance for all `a`

s that have a `Serialize`

instance.

### Serialize1

To check that a functor has a `Serialize`

instance as long as it's argument has a `Serialize`

instance, we introduce a new type class, `Serialize1`

. For those functors whose `Serialize`

instance was already defined based on a `Serialize`

instance for the argument, we can generate the new serialize instance by `default`

.

```
class Serialize1 f where
put1 :: Serialize a => Putter (f a)
get1 :: Serialize a => Get (f a)
default put1 :: (Serialize a, Serialize (f a)) => Putter (f a)
put1 = put
default get1 :: (Serialize a, Serialize (f a)) => Get (f a)
get1 = get
```

The first two functors, `FooF`

and `Surround a b`

, can use the default instances for the new class:

```
instance Serialize1 FooF
instance (Serialize a, Serialize b) => Serialize1 (Surrounded a b)
```

`Compose f g`

needs a bit of help.

```
-- Type to help defining Compose's Serialise1 instance
newtype SerializeByF f a = SerializeByF { unSerialiseByF :: f a }
instance (Serialize1 f, Serialize a) => Serialize (SerializeByF f a) where
put = put1 . unSerialiseByF
get = fmap SerializeByF get1
instance (Serialize1 f) => Serialize1 (SerializeByF f)
```

Now we can define a `Serialize1`

instance for `Compose f g`

in terms of serializing by the other two `Serialize1`

instances. `fmap SerializeByF`

tags `f`

's inner data to be serialized by `g`

's `Serialize1`

instance.:

```
instance (Functor f, Serialize1 f, Serialize1 g) => Serialize1 (Compose f g) where
put1 = put . SerializeByF . fmap SerializeByF . getCompose
get1 = fmap (Compose . fmap unSerializeByF . unSerializeByF ) get
```

### Serialize Free

Now we should be equipped to make a `Serialize`

instance for `Free f a`

. We will borrow the serialization of `Either a (SerializeByF f (Free f a))`

.

```
toEitherRep :: Free f a => Either a (SerializeByF f (Free f a))
toEitherRep (Pure a) = Left a
toEitherRep (Free x) = Right (SerializeByF x)
fromEitherRep :: Either a (SerializeByF f (Free f a)) => Free f a
fromEitherRep = either Pure (Free . unSerializeByF)
instance (Serialize a, Serialize1 f) => Serialize (Free f a) where
put = put . toEitherRep
get = fmap fromEitherRep get
instance (Serialize1 f) => Serialize1 (Free f)
```

## Example

Now we can serialize and deserialize things like:

```
example :: Free (Compose (Surrounded String Int) FooF) ()
example = Free . Compose . surround "First" 1 . Foo "FirstFoo" . Free . Compose . surround "Second" 2 . Bar 22 . Pure $ ()
```

## Boilerplate

The above requires the following extensions

```
{-# LANGUAGE DeriveFunctor #-}
{-# LANGUAGE DeriveGeneric #-}
{-# LANGUAGE DefaultSignatures #-}
{-# LANGUAGE StandaloneDeriving #-}
{-# LANGUAGE FlexibleContexts #-}
```

and the following libraries:

```
import Control.Monad.Free
import Data.Functor.Compose
import Data.Serialize
import GHC.Generics
```

other way around, that is, constructing the structure from parsed input. – fho Apr 24 '14 at 14:22`Free FooF`

instead of parsing into`FooF x`

? I presume you can parse into`FooF x`

for all`x`

that you can parse? – Cirdec Apr 24 '14 at 14:59`data Surrounded a b f x = Surrounded a (f x) b`

. Then, if you are adding, say a`String`

before and an`Int`

after, you would be parsing into`Free (Surrounded String Int FooF)`

. – Cirdec Apr 24 '14 at 15:21