Is it possible to make a generic function that would take either Foo or Bar as an argument and would return a function that uses that argument in its pattern matching?

For instance, if I have

isFoo :: SomeData -> Bool
isFoo (Foo _) = True
isFoo _       = False

isBar :: SomeData -> Bool
isBar (Bar _) = True
isBar _       = False

Is there a way to create a generic function, something like

checkType :: SomeClass -> SomeData -> Bool
checkType (SomeClass _) = True
checkType _ = False

I realize the situation looks a little odd, and the actual use case is a little more complex, but the problem is identical.

The actual code I'm trying to refactor is the following

isString :: [LispVal] -> ThrowsError LispVal
isString [(String _)] = return $ Bool True
isString ((String _):xs) = isString xs >>= unpackBool >>= return . Bool
isString _ = return $ Bool False

isSymbol :: [LispVal] -> ThrowsError LispVal
isSymbol [(Atom _)] = return $ Bool True
isSymbol ((Atom _):xs) = isSymbol xs >>= unpackBool >>= return . Bool
isSymbol _ = return $ Bool False

isNumber :: [LispVal] -> ThrowsError LispVal
isNumber [(Number _)] = return $ Bool True
isNumber ((Number _):xs) = isNumber xs >>= unpackBool >>= return . Bool
isNumber _ = return $ Bool False

So I'd like some way to make this more dry

  • You mean if there's a generic way to check if a value was constructed with a particular constructor? No, I don't think so. Actually, I'm fairly sure that's not possible. Maybe if you'd describe your use case we could figure out a way to do what you wanna do anyway?
    – Cubic
    Dec 25, 2013 at 15:59
  • 1
    Perhaps if you tell us a little about what you are actually trying to do, there could be a better way. See the xy problem. Note: I'm a beginner in Haskell, so I wouldn't really know.
    – Shahbaz
    Dec 25, 2013 at 15:59
  • Haskell has a lot of Generic Programming libraries which might allow this kind of thing. Dec 25, 2013 at 16:12
  • I think you van do it with Template Hsskell. Dec 25, 2013 at 16:36
  • 2
    Also, for instances of Generic constructor names are avaiable as strings, and it's derivable. I'm not sure you can automatically derive something more efficient though. Dec 25, 2013 at 16:59

4 Answers 4


Prisms from the lens library can act as "first-class patterns". To define prisms for your datatype:

{-# LANGUAGE TemplateHaskell #-}

import Control.Lens

data SomeData = Foo Int 
              | Bar Char

-- Will create prisms named _Foo and _Bar
$(makePrisms ''SomeData)

Since Prisms are valid Folds, we can pass them to the has function from Control.Lens.Fold:

*Main> has _Foo (Foo 5)
*Main> has _Bar (Foo 5)

Another interesting application of prisms as first-class patterns is "overriding" the behaviour of a function for cases in which the argument matches the prism. You can use outside from Control.Lens.Prism to do that. outside is a function that takes a Prism and returns a Lens for functions, that allows you to "set" the special case. For example:

functionToOverride :: SomeData -> Int
functionToOverride = const 5

-- If the arg is a Foo, return the contained int + 1 
newFunction :: SomeData -> Int
newFunction = functionToOverride & outside _Foo .~ succ

Testing both functions:

*Main> functionToOverride (Foo 77)
*Main> newFunction (Bar 'a')
*Main> newFunction (Foo 77)
{-# LANGUAGE DeriveDataTypeable #-}
import Data.Data
import Data.Typeable

data Foo a = Foo1 a | Foo2 a deriving (Data, Typeable)

data Bar a = Bar1 a | Bar2 a deriving (Data, Typeable)

checkType :: Data a => Constr -> a -> Bool
checkType c v = c == toConstr v


zeroFoo1 = Foo1 (0 :: Int)

isFoo1 = checkType (toConstr zeroFoo1)

to generalize over a your checkType, you need a constant value (e.g. mempty) for each constructor.

(really, the only trick is toConstr a == toConstr b)


Currently this isn't possible, although some extensions that would allow it are in the works.

The closest workaround currently is probably to provide a function that matches on the appropriate pattern:

isString :: [LispVal] -> ThrowsError LispVal
isString [(String _)] = return $ Bool True
isString ((String _):xs) = isString xs >>= unpackBool >>= return . Bool
isString _ = return $ Bool False

You can replace the top pattern match with a function:

isLispVal :: (LispVal -> Bool) -> [LispVal] -> ThrowsError LispVal
isLispVal p [x] | p x = return $ Bool True
isLispVal p (x:xs) | p x = isLispVal p xs >>= unpackBool >>= return . Bool
isLispVal p _ = return $ Bool False

When I've done this, I've often ended up needed proper lenses instead of just predicate functions, but it depends on the use case.


It seems that your isString function is just a lifting of the all function.

Consider this:

data LispVal = Str String | B Bool | Sym String | Num Integer

isLispStr (Str _) = True
isLispStr _ = False

isLispNum (Num _) = True
isLispNum _ = False

isLispSym (Sym _) = True
isLispSym _ = False

-- etc. for the other LispVal constructors.

Now consider these functions:

isString' :: [LispVal] -> LispVal
isString' = B . all isLispStr

isSymbol' :: [LispVal] -> LispVal
isSymbol' = B . all isLispSym

-- ...

These are the "pure" (i.e. non-monadic) versions of your isString and isSymbol functions. The monadic versions are just:

isString = return . isString'
isSymbol = return . isSymbol'


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