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Let's say I'm creating a data pipeline which will process text files. I have the following types and functions:

data A = A deriving (Show, Typeable)
data B = B deriving (Show, Typeable)
data C = C deriving (Show, Typeable)
data D = D deriving (Show, Typeable)

step1 :: A -> B
step2 :: B -> C
step3 :: C -> D

For each of the functions step{1..3} below I would like to be able to do produce a new file from an existing file, doing something like:

interact (lines . map (show . step . read) . unlines)

I then want to be able to arrange them into a graph (so functions can have multiple inputs) to achieve the following:

  1. I can traverse the data structure to tell which functions provide inputs to which others

  2. The data structure will type check at compile time so that any invalid arrangement throws a type error.

I know how to do 1 without 2 (give them a common typeclass), and I know how to do 2 without 1 (just use (.)), but I'm not sure how to do both at once. Any ideas? TIA.


AndrewC's answer is pretty much spot on and gets me most of the way there, since I can then build the graph of metadata (names) using a Map and type check it separately at the same time, however I also need some flexible polymorphism. The example below solves this but with 2 serious caveats:

  1. I'm not forced to be exhaustive in pattern matching in step4.
  2. It's tedious; there could be dozens of these "BorC" style polymorphic types, which do nothing except enable polymorphism, and not even very safely (see 1). I tried to pattern match on members of a type class (Step4Input with instances for B and C) but that didn't work (it said Couldn't match type B with C).
data BorC = ItsB B | ItsC C

step4 :: BorC -> D
step4 x = case x of { ItsB b -> D; ItsC c -> D }

-- step1    step2
--    \       /
--   ItsB   ItsC
--     \   /
--     step4
share|improve this question
It sounds sort of like you want to have a type-level graph; this is probably possible, but certainly going to be a lot of work... Will the graph be changing at runtime, or is a static graph sufficient? – Daniel Wagner Jul 20 '13 at 15:25
It's static; AndrewC's answer below gets me part of the way there, but there's something missing for me to be able to make a graph with it. Will update question. – Scott Jul 20 '13 at 17:09

I may be misunderstanding your problem, but why not simply wrap the functions up with a name?
It seems a very straightforward approach to the situation which doesn't require a lot of messing about.

module NamedFunctions where

import Control.Category        -- so I can generalise (.)
import Prelude hiding ((.),id) -- don't worry, available from Category

Store a list of function names you've composed along with the function itself:

data Fn name a b = Fn {names::[name],apply:: (a -> b)} 

When you show a function, just show what you composed to get there:

instance Show name => Show (Fn name a b) where
  show f = show $ names f

Define new versions of (.) and ($):

infixr 9 ...
(...) :: Fn name b c -> Fn name a b -> Fn name a c
f ... g = Fn (names f ++ names g) (apply f . apply g)

infixr 0 $$$
($$$) :: Fn name a b -> a -> b
f $$$ x = apply f x

and reclaim (.) to work on named functions

instance Category (Fn name) where
   (.) = (...)
   id = Fn [] id

You can leave functions you don't care about unnamed so they don't contribute to the names list.

name  n f = Fn [n] f
unnamed f = Fn []  f

You can use whatever data you like to name each function, for example:

timesThree = name "(*3)" (*3)
addFour = name "(+4)" (+4)

step1 :: Fn Int A B 
step1 = name 1 undefined
step2 :: Fn Int B C 
step2 = name 2 undefined
step3 :: Fn Int C D 
step3 = name 3 undefined

*NamedFunctions> timesThree . addFour
*NamedFunctions> timesThree . addFour $$$ 5
*NamedFunctions> step3.step2.step1
*NamedFunctions> step3.step2.step1 $$$ A
*** Exception: Prelude.undefined
share|improve this answer
This is a great answer but it doesn't seem to allow for functions to have multiple inputs. I think I wasn't clear enough in my question, sorry about that! – Scott Jul 20 '13 at 21:40
@Scott I don't understand how you could use that graph other than to show possible routes from String to String. The data type BorC is actually a single data type which you could well have called E, and you have two functions, ItsB::B->E and ItsC::C->E. If you actually plan on applying the functions to data, you have to decide which sequence of functions. Any genuinely unresolved polymorphism would give an ambiguous type error, much as would. Did you want a graph of all the possible routes? – AndrewC Jul 20 '13 at 23:57
It was for a data pipeline library. Messed around with it some more recently, what eventually gave me what I needed was building the graph in functions that close over their input types. That way I got the homogenous traversable graph, plus the possibility to assemble the graph of typed functions. I suppose the easier way would have been to just use Dynamic :). – Scott Dec 9 '14 at 0:05

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