map takes a function and a list and applies the function to every element of the list. e.g.,
(map f [x1 x2 x3]) ;= [(f x1) (f x2) (f x3)]
Mathematically, a list is a partial function from the natural numbers ℕ. If x : ℕ → X is some list, and f : X → Y is some function, then map takes the pair (f, x) to the list f○x : ℕ → Y. Therefore, map and comp return the same value, at least in the simple case.
However, when we apply map with more than one argument, there's something more complex going on. Consider the example:
(map f [x1 x2 x3] [y1 y2 y3]) ;= [(f x1 y1) (f x2 y2) (f x3 y3)]
Here, we have two lists x : ℕ → X and y : ℕ → Y with the same domain, and a function of type f : X → (Y → Z). In order to evaluate on the tuple (f, x, y), map has to do some more work behind the scenes.
First, map constructs the diagonal product list diag(x, y) : ℕ → X × Y, which is defined by diag(x, y)(n) = (x(n), y(n)).
Second, map uncurries the function to curry-1(f) : X × Y → Z. Finally, map composes these operations to get curry-1(f) ○ diag(x, y) : ℕ → Z.
My question is: does this pattern generalize? Namely, suppose that we have three lists x : ℕ → X, y : ℕ → Y and z : ℕ → Z, and a function f : X → (Y → (Z → W))). Does map send the tuple (f, x, y, z) to the list curry-2(f) ○ diag(x, y, z) : ℕ → W?