I made this function in Python:

def calc(a): return lambda op: {
    '+': lambda b: calc(a+b),
    '-': lambda b: calc(a-b),
    '=': a}[op]

So you can make a calculation like this:


And the result will be 5.

I wanbt to make the same function in Haskell to learn about lambdas, but I am getting parse errors.

My code looks like this:

calc :: Int -> (String -> Int)
calc a = \ op 
    | op == "+" = \ b calc a+b
    | op == "-" = \ b calc a+b
    | op == "=" = a

main = calc 1 "+" 1 "+" 10 "-" 7 "="
  • 1
    What haskell resources are you using? What you have posted makes no sense.
    – user1198582
    Nov 28, 2021 at 21:14
  • 1
    I am just googeling haskell return lambda and improvising a bit. I was hoping the python example would help to make it make more sense.
    – mama
    Nov 28, 2021 at 21:17
  • 7
    Why doesn't it make sense for someone who is trying to learn Haskell? Instead of criticizing them with general words, explain to them why that is not possible in Haskell? Is it maybe because Haskell is strongly typed and doesn't allow 2 different return types for one function like Python does? Are there any workarounds? I'm new to Haskell and curious about this problem @MichaelLitchard
    – user1984
    Nov 28, 2021 at 21:17
  • 3
    The code in the question makes no sense to a Haskell compiler, for sure, but a human can see how it was an attempt to replicate the Python code and explain why it's wrong.
    – amalloy
    Nov 28, 2021 at 22:04
  • 2
    very nice! thank you for asking. :)
    – Will Ness
    Nov 29, 2021 at 11:10

4 Answers 4


There are numerous syntactical problems with the code you have posted. I won't address them here, though: you will discover them yourself after going through a basic Haskell tutorial. Instead I'll focus on a more fundamental problem with the project, which is that the types don't really work out. Then I'll show a different approach that gets you the same outcome, to show you it is possible in Haskell once you've learned more.

While it's fine in Python to sometimes return a function-of-int and sometimes an int, this isn't allowed in Haskell. GHC has to know at compile time what type will be returned; you can't make that decision at runtime based on whether a string is "=" or not. So you need a different type for the "keep calcing" argument than the "give me the answer" argument.

This is possible in Haskell, and in fact is a technique with a lot of applications, but it's maybe not the best place for a beginner to start. You are inventing continuations. You want calc 1 plus 1 plus 10 minus 7 equals to produce 5, for some definitions of the names used therein. Achieving this requires some advanced features of the Haskell language and some funny types1, which is why I say it is not for beginners. But, below is an implementation that meets this goal. I won't explain it in detail, because there is too much for you to learn first. Hopefully after some study of Haskell fundamentals, you can return to this interesting problem and understand my solution.

calc :: a -> (a -> r) -> r
calc x k = k x

equals :: a -> a
equals = id

lift2 :: (a -> a -> a) -> a -> a -> (a -> r) -> r
lift2 f x y = calc (f x y)

plus :: Num a => a -> a -> (a -> r) -> r
plus = lift2 (+)

minus :: Num a => a -> a -> (a -> r) -> r
minus = lift2 (-)
ghci> calc 1 plus 1 plus 10 minus 7 equals

1 Of course calc 1 plus 1 plus 10 minus 7 equals looks a lot like 1 + 1 + 10 - 7, which is trivially easy. The important difference here is that these are infix operators, so this is parsed as (((1 + 1) + 10) - 7), while the version you're trying to implement in Python, and my Haskell solution, are parsed like ((((((((calc 1) plus) 1) plus) 10) minus) 7) equals) - no sneaky infix operators, and calc is in control of all combinations.

  • 1
    This very similar to what C. Okasaki does in "Techniques for Embedding Postfix Languages in Haskell"
    – pedrofurla
    Nov 28, 2021 at 23:44
  • 1
    After a quick experiment I saw that in GHC 8 Bool -> forall a. Maybe a unifies with forall a. Bool -> Maybe a, but this is no longer the case in GHC 9. I guess foralls are no longer hoisted. Weirdly, even in GHC8 type arguments need to be passed in the right position f True @T vs f @T True.
    – chi
    Nov 29, 2021 at 0:11
  • 2
    I can reproduce it in 9.2: the code builds fine, but the GHCi demo only runs with ImpredicativeTypes. This almost surely has to do with simplified subsumption. In particular, no extensions would be needed if we were to eta-expand everything: calc 1 $ \x -> plus x 1 $ \x -> plus x 10 $ \x -> minus x 7 equals. I guess ImpredicativeTypes helps because the Quick Look inference it enables is able to figure out the right thing to do here.
    – duplode
    Nov 29, 2021 at 0:33
  • 2
    @duplode I found an even easier way to make it work than that: just get rid of the Calc type synonym, and write out (a -> r) -> r everywhere instead. And that also has the bonus that you don't need to enable any extensions anymore. Nov 29, 2021 at 3:09
  • 2
    @JosephSible-ReinstateMonica A compromise solution might be keeping the synonym but not hiding r (type Calc r a = (a -> r) -> r).
    – duplode
    Nov 29, 2021 at 3:41

chi's answer says you could do this with "convoluted type class machinery", like printf does. Here's how you'd do that:

{-# LANGUAGE ExtendedDefaultRules #-}

class CalcType r where
    calc :: Integer -> String -> r

instance CalcType r => CalcType (Integer -> String -> r) where
    calc a op
        | op == "+" = \ b -> calc (a+b)
        | op == "-" = \ b -> calc (a-b)

instance CalcType Integer where
    calc a op
        | op == "=" = a

result :: Integer
result = calc 1 "+" 1 "+" 10 "-" 7 "="

main :: IO ()
main = print result

If you wanted to make it safer, you could get rid of the partiality with Maybe or Either, like this:

{-# LANGUAGE ExtendedDefaultRules #-}

class CalcType r where
    calcImpl :: Either String Integer -> String -> r

instance CalcType r => CalcType (Integer -> String -> r) where
    calcImpl a op
        | op == "+" = \ b -> calcImpl (fmap (+ b) a)
        | op == "-" = \ b -> calcImpl (fmap (subtract b) a)
        | otherwise = \ b -> calcImpl (Left ("Invalid intermediate operator " ++ op))

instance CalcType (Either String Integer) where
    calcImpl a op
        | op == "=" = a
        | otherwise = Left ("Invalid final operator " ++ op)

calc :: CalcType r => Integer -> String -> r
calc = calcImpl . Right

result :: Either String Integer
result = calc 1 "+" 1 "+" 10 "-" 7 "="

main :: IO ()
main = print result

This is rather fragile and very much not recommended for production use, but there it is anyway just as something to (eventually?) learn from.

  • 1
    It's far from being pretty, but I expected it to be even worse. Having a trailing "=" seems to help. printf has no such "luxury", if we can call it so. (+1)
    – chi
    Nov 29, 2021 at 16:01

Here is a simple solution that I'd say corresponds more closely to your Python code than the advanced solutions in the other answers. It's not an idiomatic solution because, just like your Python one, it will use runtime failure instead of types in the compiler.

So, the essence in you Python is this: you return either a function or an int. In Haskell it's not possible to return different types depending on runtime values, however it is possible to return a type that can contain different data, including functions.

data CalcResult = ContinCalc (Int -> String -> CalcResult)
                | FinalResult Int

calc :: Int -> String -> CalcResult
calc a "+" = ContinCalc $ \b -> calc (a+b)
calc a "-" = ContinCalc $ \b -> calc (a-b)
calc a "=" = FinalResult a

For reasons that will become clear at the end, I would actually propose the following variant, which is, unlike typical Haskell, not curried:

calc :: (Int, String) -> CalcResult
calc (a,"+") = ContinCalc $ \b op -> calc (a+b,op)
calc (a,"-") = ContinCalc $ \b op -> calc (a-b,op)
calc (a,"=") = FinalResult a

Now, you can't just pile on function applications on this, because the result is never just a function – it can only be a wrapped function. Because applying more arguments than there are functions to handle them seems to be a failure case, the result should be in the Maybe monad.

contin :: CalcResult -> (Int, String) -> Maybe CalcResult
contin (ContinCalc f) (i,op) = Just $ f i op
contin (FinalResult _) _ = Nothing

For printing a final result, let's define

printCalcRes :: Maybe CalcResult -> IO ()
printCalcRes (Just (FinalResult r)) = print r
printCalcRes (Just _) = fail "Calculation incomplete"
printCalcRes Nothing = fail "Applied too many arguments"

And now we can do

ghci> printCalcRes $ contin (calc (1,"+")) (2,"=")

Ok, but that would become very awkward for longer computations. Note that we have after two operations a Maybe CalcResult so we can't just use contin again. Also, the parentheses that would need to be matched outwards are a pain.

Fortunately, Haskell is not Lisp and supports infix operators. And because we're anyways getting Maybe in the result, might as well include the failure case in the data type.

Then, the full solution is this:

data CalcResult = ContinCalc ((Int,String) -> CalcResult)
                | FinalResult Int
                | TooManyArguments

calc :: (Int, String) -> CalcResult
calc (a,"+") = ContinCalc $ \(b,op) -> calc (a+b,op)
calc (a,"-") = ContinCalc $ \(b,op) -> calc (a-b,op)
calc (a,"=") = FinalResult a

infixl 9 #
(#) :: CalcResult -> (Int, String) -> CalcResult
ContinCalc f # args = f args
_ # _ = TooManyArguments

printCalcRes :: CalcResult -> IO ()
printCalcRes (FinalResult r) = print r
printCalcRes (ContinCalc _) = fail "Calculation incomplete"
printCalcRes TooManyArguments = fail "Applied too many arguments"

Which allows to you write

ghci> printCalcRes $ calc (1,"+") # (2,"+") # (3,"-") # (4,"=")
  • I'm wondering if implementing the Applicative for CalcResult would lead to a more Haskellesque use?
    – user1984
    Nov 29, 2021 at 6:34
  • 1
    @user1984 CalcResult can't be Applicative, because it has no type parameter. Maybe there is some meaningful generalization of it which is Applicative, but nothing jumps out at me.
    – amalloy
    Nov 30, 2021 at 11:08
  • @amalloy Oh, right! Totally forgot that they need to be higher kinded (if that's the right term to use for it. I mean being of kind * -> *) :D
    – user1984
    Nov 30, 2021 at 11:11

A Haskell function of type A -> B has to return a value of the fixed type B every time it's called (or fail to terminate, or throw an exception, but let's neglect that).

A Python function is not similarly constrained. The returned value can be anything, with no type constraints. As a simple example, consider:

def foo(b):
   if b:
      return 42        # int
      return "hello"   # str

In the Python code you posted, you exploit this feature to make calc(a)(op) to be either a function (a lambda) or an integer.

In Haskell we can't do that. This is to ensure that the code can be type checked at compile-time. If we write

bar :: String -> Int
bar s = foo (reverse (reverse s) == s)

the compiler can't be expected to verify that the argument always evaluates to True -- that would be undecidable, in general. The compiler merely requires that the type of foo is something like Bool -> Int. However, we can't assign that type to the definition of foo shown above.

So, what we can actually do in Haskell?

One option could be to abuse type classes. There is a way in Haskell to create a kind of "variadic" function exploiting some kind-of convoluted type class machinery. That would make

calc 1 "+" 1 "+" 10 "-" 7 :: Int

type-check and evaluate to the wanted result. I'm not attempting that: it's complex and "hackish", at least in my eye. This hack was used to implement printf in Haskell, and it's not pretty to read.

Another option is to create a custom data type and add some infix operator to the calling syntax. This also exploits some advanced feature of Haskell to make everything type check.

{-# LANGUAGE GADTs, FunctionalDependencies, TypeFamilies, FlexibleInstances #-}

data R t where
   I :: Int -> R String
   F :: (Int -> Int) -> R Int

instance Show (R String) where
    show (I i) = show i

type family Other a where
   Other String = Int
   Other Int    = String

(#) :: R a -> a -> R (Other a)
I i # "+" = F (i+)   -- equivalent to F (\x -> i + x)
I i # "-" = F (i-)   -- equivalent to F (\x -> i - x)
F f # i   = I (f i)
I _ # s   = error $ "unsupported operator " ++ s

main :: IO ()
main =
   print (I 1 # "+" # 1 # "+" # 10 # "-" # 7)

The last line prints 5 as expected.

The key ideas are:

  • The type R a represents an intermediate result, which can be an integer or a function. If it's an integer, we remember that the next thing in the line should be a string by making I i :: R String. If it's a function, we remember the next thing should be an integer by having F (\x -> ...) :: R Int.

  • The operator (#) takes an intermediate result of type R a, a next "thing" (int or string) to process of type a, and produces a value in the "other type" Other a. Here, Other a is defined as the type Int (respectively String) when a is String (resp. Int).

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