# Clojure: how is map different from comp?

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 : XY 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 → (YZ). 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 × YZ. 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 → (ZW))). Does map send the tuple (f, x, y, z) to the list curry-2(f) ○ diag(x, y, z) : ℕ → W?

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It seems that the question title has little to do with the question actually asked in the body; I'll try to address both issues.

### The Clojure side

As evidenced by examples like `(map inc [1 2 3])` and `(comp inc [1 2 3])` -- both of which, incidentally, make perfect sense in Clojure -- the Clojure functions `map` and `comp` operate completely differently even in the one sequence case. `map` simply does not treat its sequence arguments as functions in the software sense of callable objects, whereas `comp` treats all of its arguments in this way; `map` returns a compound datum, whereas `comp` does not; the value returned by `comp` is callable as a function, whereas `map`'s returns values are not; etc.

(Other functional languages similarly have separate "map" and "compose" higher-order functions; in Haskell, these are `map` (and the more general `fmap`) and `(.)`.)

Notably, `map` performs no actual in-memory tupling-up of arguments to its input function and does not apply any deschönfinkelizing / uncurrying transformation to the input function.

### The mathematical side

The pattern does of course generalize fine, though it's worth keeping in mind that what's a function of what etc. -- under the hood of the model, as it were -- depends on the choice of representation which tends to be arbitrary. Finite sequences can be represented perfectly well as (total) functions with finite ordinals as domains, or as Kuratowski tuples, or in the way which you describe where you don't care about your lists not necessarily being "gapless" etc. Depending on the representational choices, the concept of natural numbers might not enter the picture at all, the objects representing lists may or may not look like functions whose codomain is a superset of the set of the list's entries etc.

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what does "deschönfinkelizing" mean? Are you referring to en.wikipedia.org/wiki/Moses_Sch%C3%B6nfinkel? –  spike Sep 17 '13 at 23:04
@spike The same as "uncurrying"; and yes, the name refers to Schönfinkel who introduced the concept. (I wonder if I should have spelled it "deschönfinkeling", though.) –  Michał Marczyk Sep 17 '13 at 23:21

I don't know if it helps, but:

• Clojure doesn't have currying, like Haskell. It does have partial function application, but it's not the same as currying.
• Clojure's map is more like zipWith, zipWith3, etc in Haskell
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`map` produces a lazy sequence that will compute a sequence when the result is finally read. So it it returns a sequence not strictly the result your type expression implies. It also adds the overhead of sequences and changes the evaluation order because it is lazy and chunked.
Well, `map` simply returns different values from `comp` when both are passed the same arguments (that's on the assumption that it's a set of arguments which makes sense for both, which of course might not be the case), so I don't know that it's fair to say it introduces overhead which `comp` does not. @MichielBorkent Interleaving of evaluation at different layers of a multilayer seq-transforming pipeline changes in the presence of chunking. (`(filter odd? (map inc [1 2 3]))` -> all incrementing happens before all filtering; with a longer vector they'd be interleaved.) –  Michał Marczyk Sep 17 '13 at 19:31