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,"=")
3
```

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,"=")
2
```