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.

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?



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)
    a = f2 e
    b = f1 a

alterParamState :: (a -> b) -> (m -> (a, m)) -> (m -> (b, m))
alterParamState f1 f2 = alterParamStateHelper f1 h1
    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)
  • 2
    fmap does not take two Tests, it has signature fmap :: (a -> b) -> Test m a -> Test m b here. Oct 28, 2019 at 17:53
  • 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.
    – Redu
    Oct 28, 2019 at 18:30

1 Answer 1


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

There is a problem with your fmap signature here. fmap has signature fmap :: Functor f => (a -> b) -> f a -> f b so if f ~ Test m, then the signature is fmap :: (a -> b) -> Test m a -> Test m b.

We thus can here define an fmap where we "post-process" the result of the function. We thus construct a new function that will use the old function to construct a 2-tuple (a, m), and then call f on the first item, such that we construct a tuple (b, m):

import Control.Arrow(first)

instance Functor (Test m) where
    fmap f (Test g) = Test (first f . g)
  • Thanks! To be sure I fully understood all the concepts at play here I added my own solution to the original question without using Arrow. Does my solution look valid?
    – mBrice1024
    Oct 29, 2019 at 1:16
  • 1
    @mBrice1024: without the first, you can write it as fmap f (Test g) = Test (\x -> let (a, b) = g x in (f a, b)) Oct 29, 2019 at 7:45
  • 1
    Nice, way more concise. I forgot about let, in.
    – mBrice1024
    Oct 29, 2019 at 13:18

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