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Say I have something silly like this:

data SomeType
    = Unary Int
    | Associative SomeType
    | Binary SomeType SomeType

some_func :: SomeType -> Int
some_func s =
    case s of
        Unary n -> n
        Associative s1 -> some_func s1
        Binary s1 s2 -> some_func s1 + some_func s2

Here some_func will look through all SomeTypes in a given SomeType and sum up the Ints of all Unary data constructors. SomeType is a recursive data type.

In these pattern matches I'm repeating some_func s1. Is there a way to use @, when, let or anything else to declare sf1 = some_func s1 and use it in both? Something like this:

data SomeType
    = Unary Int
    | Associative SomeType
    | Binary SomeType SomeType

some_func :: SomeType -> Int
some_func s =
    case s of
        Unary n -> n
        Associative s1 -> sf1
        Binary s1 s2 -> sf1 + sf2
        where
            sf1 = some_func s1
            sf2 = some_func s2

The problem here is that s1 and s2 are only known in the block after -> and sf1 can't be calculated.

share|improve this question
    
What are s1 and s2, I can't see their definition. You got s as parametr, and define after where only sf1 and sf2. – Grzegorz Łuszczek Apr 21 '12 at 6:58
1  
s1 and s2 are of SomeType, they're from the pattern match in the cases – Aram Kocharyan Apr 21 '12 at 6:59
up vote 5 down vote accepted

Abuse record syntax!

data SomeType
    = Unary { u :: Int }
    | Associative { s1 :: SomeType }
    | Binary { s1, s2 :: SomeType }

someFunc :: SomeType -> Int
someFunc s = case s of
    Unary{}       -> u s
    Associative{} -> sf1
    Binary{}      -> sf1 + sf2
  where
    sf1 = someFunc (s1 s)
    sf2 = someFunc (s2 s)

Note that different constructors of the same type are allowed to have the same named fields in their records. Laziness prevents you from erroring on sf2 if you go down the Associative branch.

share|improve this answer
1  
I think this is the simplest and most elegant solution, nicely done. – Aram Kocharyan Apr 22 '12 at 2:40

This doesn't answer the question but might solve the problem:

{-# LANGUAGE DeriveFoldable #-}
module SomeType where
import Data.Foldable as F

data SomeType a
    = Unary a
    | Associative (SomeType a)
    | Binary (SomeType a) (SomeType a)
      deriving (Foldable)

some_func :: SomeType Int -> Int
some_func = F.foldl1 (+)
share|improve this answer

The answer is no: the s1 in Associative is different to the s1 in Binary. The fact that they have the same name is a distraction, because they exist in different contexts.

I guess you could save some typing by using a helper but this doesn't really help encapsulate the repeated logic:

some_func :: SomeType -> Int
some_func s = go s
  where go (Unary n) = n
        go (Associative s1) = go s1
        go (Binary s1 s2) = go s1 + go s2
share|improve this answer
    
darn, thanks for the info! – Aram Kocharyan Apr 21 '12 at 7:51
    
some_func s = go s - I see no purpose in writing this in terms of go, why not just pattern match directly at the some_func level? This was only suggested to "save some typing"? I'd discourage using a helper function that adds no value, even if it saves a few keystrokes. – Dan Burton Apr 21 '12 at 16:02
    
@DanBurton, the "I guess" was very reluctant. I agree that it is almost entirely pointless. – huon Apr 21 '12 at 16:17

I'm not sure if this'll make it shorter in this specific case, but in the more general case, you should check out Scrap Your Boilerplate. For example:

{-# LANGUAGE Rank2Types, DeriveDataTypeable, NoMonomorphismRestriction #-}

import Data.Generics

data SomeType
    = Unary Int
    | Associative SomeType
    | Binary SomeType SomeType
    deriving (Data, Typeable, Show)

flatten_sometype x@(Unary _) = x
flatten_sometype (Associative s) = s
flatten_sometype (Binary (Unary a) (Unary b)) = Unary $ a + b

some_func2 = let Unary n = everywhere (mkT flatten_sometype)
             in  n

As you can see, by using everywhere, I need only specify a local transformation - SYB takes care of all the recursion. Where this really comes in handy is when you have multiple types involved; SYB will happily tunnel through types you aren't transforming and transform their arguments as well. Be careful how much you use it though - it can lead to a ton of GC churn if overused.

share|improve this answer
    
what's the type signature of flatten_sometype? – Aram Kocharyan Apr 21 '12 at 10:14
    
@AramKocharyan: SomeType → SomeType. But mind you, it isn't total function. – Vitus Apr 21 '12 at 10:33
    
The type of some_func2 is also SomeType -> SomeType, right? Whereas the original some_func was SomeType -> Int. I take it the desired result is in a Unary constructor? – ben w Apr 21 '12 at 16:35
    
Oops, fixed. :) – bdonlan Apr 21 '12 at 17:01

Shortest way to write it should simply be pattern-matching:

some_func :: SomeType -> Int
some_func (Unary n) = n
some_func (Associative s) = some_func s
some_func (Binary s1 s2) = (some_func s1) + (some_func s2)

There is still repetition of the pieces, so it probably doesn't answer your question ... Maybe something involving defining some_func in terms of fmap some_func?

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