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Very often when I write something using Haskell I need records with multiple constructors. E.g. I want to develop some kind of logic schemes modelling. I came up to such type:

data Block a = Binary {
      binOp  :: a -> a -> a
    , opName :: String
    , in1 :: String
    , in2 :: String
    , out :: String
} | Unary {
      unOp  :: a -> a
    , opName :: String
    , in_ :: String
    , out :: String
}

It describes two types of blocks: binary (like and, or etc.) and unary (like not). They contain core function, input and output signals.

Another example: type to describe console commands.

data Command = Command { info :: CommandInfo
                       , action :: Args -> Action () }
             | FileCommand { info :: CommandInfo
                           , fileAction :: F.File -> Args -> Action ()
                           , permissions :: F.Permissions}

FileCommand needs additional field - required permissions and its action accept file as a first parameter.

As I read and search topics, books etc. about Haskell, it seems that it is not common to use types with record syntax and many constructors simultaneously.

So the question: is this "pattern" is not haskell-way and why? And if it is so, how to avoid it?

P.S. Which from proposed layouts is better, or maybe there is more readable one? Because I can't find any examples and suggestions in other sources.

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4 Answers 4

up vote 5 down vote accepted

When things start getting complicated, divide and conquer. Create complex entities by composing simpler ones, not by ramming everything into a single place. This has proven to be the optimal approach to programming in general, not just Haskell.

Both your examples can benefit from separation. E.g.

data Block a = BinaryBlock (Binary a) | UnaryBlock (Unary a)

data Binary a = Binary {
  ...
}
data Unary = Unary {
  ...
}

Now you have Binary and Unary separated and you're able to write dedicated functions for each of them in isolation. Those functions will be much simpler and easier to reason about and maintain.

You'll also be able to benefit from putting those types in separate modules, which will resolve the field names collision. The final api for Block will be abot very simple pattern matches and forwarding to specialized functions of Binary and Unary.

This approach is scalable. No matter how complex your entities or problems are you're always free to add another level of decomposition.

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This is certainly good advice for many situations, but I don't quite agree that all multi-block types should be split up. When none of the constituent blocks have any use on their own, this is mostly extra type namespace pollution without real benefits. –  leftaroundabout May 30 at 13:48
    
@leftaroundabout I never said that all multi-block types should be split up. I said that it should be done "When things start getting complicated", and OP presented just that kind of examples. –  Nikita Volkov May 30 at 13:52
    
Isn't it a little bit ugly to have such type as: data Command = SimpleCommand SimpleCommand' | FileCommand FileCommand' ? And all this repetition when create values of this type. And, as I understand correctly, I have to implement all accessor functions by myself. –  uv.nikita May 30 at 14:31
    
@uv.nikita Yes, it is a bit ugly. But it's the shortcoming of the language, not the approach. You can alternatively use aliases over Either like so: type Block = Either A (Either B (Either C D)), or declare polymorphic types similar to Either for arities bigger than 2. And yes decomposition will result in a bit more typing, but you have to understand that it's not the typing that the programmer spends most of his time on, but reasoning about the code and maintaining it. Therefore a decluttered code as a result of this approach is most valuable. –  Nikita Volkov May 30 at 15:01

A bit of a problem with such types is that the accessor functions cease to be total, which is rather frowned upon these days, for good reasons. That may be why they're avoided in books.

IMO, multi-constructor records are in principle still fine, only it needs to be understood that the labels should not be used as accessor functions. But they can nevertheless be pretty useful, in particular with the RecordWildCards extension.

Such types are certainly found in a number of libraries. When the constructors are hidden you're most definitely fine.

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I think the partiality of the accessor functions is a major drawback. However, that's only the case when we're not using lens. With it it's a lot more cozy:

{-# LANGUAGE TemplateHaskell #-}

import Control.Lens

data Block a = ...

makeLenses ''Block
makePrisms ''Block

Partiality is now wholly remedied: the generated accessors are explicitly partial or total (in other words, 1-target lenses or 0-many-target traversals):

block1 = Binary (+) "a" "b" "c" "d"
block2 = Unary id "a" "b" "x"

main = do
    print $ block1^. opName -- total accessor
    print $ block2^? in2    -- partial accessor, prints Nothing 

And we get all the other lens goodies of course.

Also, a problem with splitting out variants is that common field names will collide. With lenses we could have long non-colliding field names, and then use simple lens names overloaded via typeclasses, or makeClassy and makeFields from the lens library, but that's rather an increase in the "weight" of our solution.

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I would recommend not using ADTs and record types at the same time, simply for the reason that unOp (Binary (+) "+" "1" "2" "3") type checks without warning with -Wall, but will crash your program. It essentially circumvents the type system and I personally think that feature should be removed from GHC or you should have to make each constructor have the same fields.

What you're wanting is a sum type of two records. This is perfectly achievable and much safer with Either, and requires about as much boilerplate since you'd have to write isBinaryOp and isUnaryOp functions anyway to mirror isLeft or isRight. Additionally, Either has many functions and instances that make working with it easier, while your custom type does not. Just define each constructor as its own type:

data BinaryOp a = BinaryOp
    { binOp :: a -> a -> a
    , opName :: String
    , in1 :: String
    , in2 :: String
    , out :: String
    }
data UnaryOp a = UnaryOp
    { unOp :: a -> a
    , opName :: String
    , in_ :: String
    , out :: String
    }

type Block a = Either (BinaryOp a) (UnaryOp a)

data Command' = Command
    { info :: CommandInfo
    , action :: Args -> Action ()
    }
data FileCommand = FileCommand
    { fileAction :: F.File -> Args -> Action ()
    , permissions :: F.Permissions
    }

type Command = Either Command' FileCommand

This isn't really much more code, and it's isomorphic to your original types while taking full advantage of the type system and available functions. You can also easily write equivalent functions between the two:

-- Before
accessBinOp :: (Block a -> b) -> Block a -> Maybe b
accessBinOp f b@(BinaryOp _ _ _ _ _) = Just $ f b
accessBinOp f _ = Nothing

-- After
accessBinOp :: (BinaryOp a -> b) -> Block a -> Maybe b
accessBinOp f (Left b) = Just $ f b
accessBinOp f _ = Nothing

-- Usage of the before version
> accessBinOp in1 (BinaryOp (+) "+" "1" "2" "3")
Just "1"
> accessBinOp in_ (BinaryOp (+) "+" "1" "2" "3")
*** Exception: No match in record selector in_
-- Usage of the after version
> accessBinOp in1 (Left $ BinaryOp (+) "+" "1" "2" "3")
Just "1"
> accessBinOp in_ (Left $ BinaryOp (+) "+" "1" "2" "3")
Couldn't match type `UnaryOp a1` with `BinaryOp a0`
Expected type: BinaryOp a0 -> String
  Actual type: UnaryOp a1 -> String
...

So before, you get an exception if you use a nontotal function, but afterwards you only have total functions and can restrict your accessors so that the type system catches your errors for you, rather than the runtime.

One key difference is not f can be restricted to only working on

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It would be nice if GHC simply had a warning whenever a multiconstructor record label is used as an accessor function. –  leftaroundabout May 30 at 13:44
    
Interesting approach, but what if there will be more than two types of something? –  uv.nikita May 30 at 14:06
    
@leftaroundabout Are you suggesting that they should only be used with RecordWildCards? I think that would be acceptable, but it would be a bit awkward for beginners. I don't like the idea that enabling RecordWildCards is what enables ADT records (or them being that closely related). Rather, I think they should be highly discouraged because Haskell has every capability of handling this same structure but in a fully typesafe manner, whether it be through my example or Nikita's or another technique entirely. ADT records allow people to ignore the type system and write bad programs. –  bheklilr May 30 at 14:07
    
You're probably right. Personally, I really like RecordWildCards a lot, and I think it's also fairly intuitive for beginners, but OTOH hand it's not exactly a useful thing to use when explaing about ADTs. –  leftaroundabout May 30 at 14:18
    
@uv.nikita You could go with Nikita Volkov's suggestion and create an ADT with a constructor for each record, which would certainly keep the data types flatter, but the other route is nesting data types. Another alternative is GADTs, which can be used like record types just without accessor functions. You can only pattern match on them to extract the fields. This is safer, but a bit more tedious. –  bheklilr May 30 at 14:19

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