# Program to find the result of primitive recursive functions

I'm writing a program to solve the result of primitive recursive functions:

``````  1 --Basic functions------------------------------
2
3 --Zero function
4 z :: Int -> Int
5 z = \_ -> 0
6
7 --Successor function
8 s :: Int -> Int
9 s = \x -> (x + 1)
10
11 --Identity/Projection function generator
12 idnm :: Int -> Int -> ([Int] -> Int)
13 idnm n m = \(x:xs) -> ((x:xs) !! (m-1))
14
15 --Constructors--------------------------------
16
17 --Composition constructor
18 cn :: ([Int] -> Int) -> [([Int] -> Int)] -> ([Int] -> Int)
19 cn f [] = \(x:xs) -> f
20 cn f (g:gs) = \(x:xs) -> (cn (f (g (x:xs))) gs)
``````

these functions and constructors are defined here: http://en.wikipedia.org/wiki/Primitive_recursive_function

The issue is with my attempt to create the compositon constructor, cn. When it gets to the base case, f is no longer a partial application, but a result of the function. Yet the function expects a function as the first argument. How can I deal with this problem?

Thanks.

-
There's also a function composition operator tinyurl.com/ykts2pz and an article on how to write pointfree code haskell.org/haskellwiki/Pointfree – Yasir Arsanukaev May 10 '10 at 8:28
Just a note: in `idnm`, you needlessly pattern-match against the `:` list constructor. You can just write `idnm n m = \xs -> xs !! (m-1)`, with the `!!` operator forcing the list type; this simplifies to `idnm _ m = (!! (m-1))`. If you really want to pattern-match against `:` (perhaps to forbid `[]`), you could write `idnm _ m xs@(_:_) = xs !! (m-1)`. – Antal Spector-Zabusky May 10 '10 at 14:23
Well, all 3 functions are over complicated. `z = const 0; s = succ`. – kennytm May 10 '10 at 15:15

Given f,

``````f :: [a] -> b
``````

and g_k,

``````g_k :: [a] -> a
``````

we want to produce h,

``````h :: [a] -> b
``````

so the composition should be like

``````compo :: ([a] -> b) -> [[a] -> a] -> [a] -> b
compo f gs xs = f (map (\$ xs) gs)
``````

Edit: It can also be written in applicative style (eliminating that `\$`) as
``````compo f gs xs = f (gs <*> pure xs)