*(note: the answer is in the end of this post)* The 2nd function,

```
(define (swap-ends x) ; swap [] = []
(if (or (equal (length x) 0) (equal (length x) 1)) ; swap [x] = [x]
x ; swap (x:xs)
(cons (first (swap-ends (rest x))) ; | (a:b) <- swap xs
(swap-ends (cons (first x) ; = a : swap (x : b)
(rest (swap-ends (rest x))))))))
```

(with Haskell translation in the comments) what does it do, you ask? The data flow diagram for `if`

's alternative clause is

```
/-> first ----------------------> cons
x --> first ------/-------------> cons --> swap --/
\-> rest -> swap ---> rest ---/
```

(follow the arrows from left to right). So,

```
[] -> []
[1] -> [1]
/-> 2 -----------------------> [2,1]
[1,2] --> 1 --------/------------> [1] --> [1] --/
\-> [2] -> [2] ---> [] ---/
/-> 3 -------------------------> [3,2,1]
[1,2,3] --> 1 ------------/----------> [1,2] --> [2,1] --/
\-> [2,3] -> [3,2] -> [2] --/
/-----> 4 ----------------------------> [4,2,3,1]
[1,2,3,4] --> 1 ------------/---------------> [1,3,2] -> [2,3,1] -/
\-> [2,3,4] -> [4,3,2] -> [3,2] -/
```

So far it indeed does swap the end elements of a list. Let's prove it by the natural induction,

`true(N-1) => true(N)`

:

```
/-> N --------------------------------------> [N,2..N-1,1]
[1..N] --> 1 ---------/-----------> [1,3..N-1,2] -> [2,3..N-1,1] -/
\-> [2..N] -> [N,3..N-1,2] /
-> [3..N-1,2] -/
```

So it is proven. Thus, we need to devise a data flow diagram which, under the supposition of reversing an (N-1)-length list, will reverse an N-length list:

```
[1..N] --> 1 ------------------------------------\
\-> [2..N] -> [N,N-1..2] -> N -------------\------------------\
\-> [N-1,N-2..2] -> [2..N-1] -> [1..N-1] -> rev -> cons
```

Which gives us the implementation

```
(define (rev ls) ; rev [] = []
(cond ; rev [x] = [x]
((null? ls) ls) ; rev (x:xs)
((null? (rest ls)) ls) ; | (a:b) <- rev xs
(else ; = a : rev (x : rev b)
(cons (first (rev (rest ls)))
(rev (cons (first ls)
(rev (rest (rev (rest ls))))))))))
(rev '(1 2 3 4 5)) ; testing
;Value 13: (5 4 3 2 1)
```

The Haskell translation in the comments follows the diagram quite naturally. It is actually *readable*: `a`

is the last element, `b`

is the reversed "core" (i.e. the input list without its first and last element), so we reverse the reversed core, prepend the first element to get the *butlast* part of the input list, then reverse it and prepend the last element. *Simple.* :)