Dismiss
Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

Shorter Syntax For Cases In Haskell?

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.

-
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
s1 and s2 are of SomeType, they're from the pattern match in the cases – Aram Kocharyan Apr 21 '12 at 6:59

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.

-
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 (+)
``````
-

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
``````
-
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.

-
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`?

-