Given a functional data structure (in this case, a Tree), there are usually two general things you can do with it.
Mapping is where you take a function
f :: a -> b, and a structure
origTree :: Tree a, and apply the function to the elements of the structure, resulting in
newTree :: Tree b. (Note that the canonical way to make a structure mappable is to make it a
Functor, and define
Folding is where you somehow compound all elements of the structure into some new value. When you said you had a
Tree and the
(+) function, I immediately thought of a fold: summing all the elements in the tree. (Note that the canonical way to make a structure foldable is to make it an instance of
Foldable (surprise!) and define
However, it appears your homework task is to define a mapping function for your tree.
Now, regarding your own question, turning a function into a tree. It is a bit unclear what exactly you mean by putting
c into your tree, but let's play with the idea a bit. For the sake of simplicity, I'm not going to make a completely generic function. Also, since your function "trees" are rather lopsided, I'm calling them a
FunHistory instead of a
Tree. This will represent a history of function applications.
data FunHistory a b = Result b (FunHistory a b)
| Application (a -> FunHistory a b) a (FunHistory a b)
| Base (a -> FunHistory a b)
Now this type is a bit weird.
Result contains a result of type
b, as well as a link to the previous history of function applications.
Base contains a function with no history of function applications, and the capability of producing a future history if a value of type
a is supplied.
Application, then, is an intermediate record, which provides the capability of producing a future history, as well as noting a past history, and which value was applied to that past history.
Now let's make some functions for convenience. Strap on your seat belt, this could get bumpy.
mkHist :: (a -> b) -> FunHistory a b
mkHist f = let h = Base (\x -> Result (f x) h) in h
Given a single-argument function, we can create a history out of it by...magic. This particular flavor of magic is called "laziness" and "recursive let".
Let's move on and create a function that will take a
FunHistory and an input value, and move the history along. Sadly, this is not a total function; it is undefined for the
Result type of a
-- The caller should make sure it isn't a `Result` type before using this function
app :: a -> FunHistory a b -> FunHistory a b
app x (Result _ _) = undefined
app x (Application f _ _) = f x
app x (Base f) = f x
This is fine and dandy for single-argument functions, but the intermediate
Application constructor is never needed for such simple cases. Let's try creating a smart-constructor for a 2-argument function:
mkHist2 :: (a -> a -> b) -> FunHistory a b
mkHist2 f = let h = Base (\x -> mkHist' f x h)
mkHist' f x h = let h' = Application (\y -> Result (f x y) h') x h
Let's try it for a 3-argument function now:
mkHist3 :: (a -> a -> a -> b) -> FunHistory a b
mkHist3 f = let h = Base (\x -> mkHist2' f x h)
mkHist2' f x h = let h' = Application (\y -> mkHist' (f x) y h') x h
Now a 4-argument function:
mkHist4 :: (a -> a -> a -> b) -> FunHistory a b
mkHist4 f = let h = Base (\x -> mkHist3' f x h)
mkHist3' f x h = let h' = Application (\y -> mkHist2' (f x) y h') x h
Well look at that; these functions look almost exactly like
mkHist2' respectively! The next step from here would be to generalize these functions into a typeclass, so that it scales to functions with arbitrary numbers of inputs. The catch is that all the inputs must have the same type.
[warning: this code is untested, but I'm somewhat sure it's mostly correct...ish]
instance (Show a, Show b) => Show (FunHistory a b) where
show (Base _) = "base"
show (Application _ x h) = "app " ++ show x ++ ", " ++ show h
show (Result r h) = "result: " ++ r ++ ", " ++ show h