So let's say I want to define a newtype that houses a function:

```
newtype Test m a = Test(m -> (a, m))
```

This could be used to house state of some sort.

Now let's say I would like to implement fmap for this newtype.

```
instance Functor (Test m) where
--fmap :: (a -> b) -> Test m a -> Test m a -> b
fmap f (Test f1) (Test f2) = ?
```

Since the newtype houses functions there's no way to use pattern matching to break f1 and f2 apart.

For instance I initially thought maybe I could pass the input value of f2 into the call f1 to yield a (a, m) tuple, but I don't think you can do that.

ie

```
tup = f1 (get input of f2)
```

Is anyone able to provide me with what concepts I'm missing to deal with this scenario or is this just not possible?

Thanks

**UPDATE**

Big thanks to Redu and Willem Van Onsem.

Looks like I was lacking in understanding of how to use the composition operator (.).

Basically the key here is use (.) to grab the first element of the tuple and then do a bunch of partial function definitions to get into the state needed by fmap. Here is my fmap implementation without using the library function. Purposefully verbose to help with understanding.

```
alterParamStateHelper :: (a -> b) -> (m -> a) -> m -> (b, m)
alterParamStateHelper f1 f2 m = (b, m)
where
a = f2 e
b = f1 a
alterParamState :: (a -> b) -> (m -> (a, m)) -> (m -> (b, m))
alterParamState f1 f2 = alterParamStateHelper f1 h1
where
h1 = fst . f2--m -> a
instance Functor (Test m) where
-- fmap :: (a -> b) -> Test m a -> Test m b
fmap f1 (Test f2) = Test (alterParamState f1 f2)
```

`fmap`

does not take two`Test`

s, it has signature`fmap :: (a -> b) -> Test m a -> Test m b`

here.`fmap`

operator is defined at the Functor instance of the function type`(->) r`

as the composition operator`(.)`

. In other words applying`f`

to the result of that function. This should give you an idea.