We can go on a mystic journey and treat this definition as it is, a definition. Cryptic? This means equational reasoning, i.e. reasoning through equations, i.e. definitions. Here's what I mean. You have

```
(define (y s lis)
(cond
((null? lis) '() )
((equal? s (car lis)) lis)
(else (y s (cdr lis)))))
```

We can re-write this as two equations,

```
y s lis = lis , if (null? lis) || (equal? s (car lis))
= y s (cdr lis) , otherwise
```

Here `y s lis`

stands for *"the result of Scheme call *`(y s lis)`

" and so on.

Clearly we have two cases. One is base case, another describes a *reduction* step. Re-writing again,

```
y s lis = y s (cdr lis) , if (not (null? lis)) && (not (equal? s (car lis)))
= lis , otherwise
```

This is practically in English now. So while `lis`

is not null, and its `car`

isn't `s`

, we proceed along to its `cdr`

, and so on and so forth until either we hit the list's end, or its `car`

is `s`

, and then we stop. So when we've found `s`

, we return the list, otherwise the list is exhausted and the empty list is returned. This is otherwise known as `member`

in Common Lisp. R5RS Scheme's `member`

, as well as Racket's, returns `#f`

when no `x`

is found in the list.

Where is the *equational* reasoning here, you ask? In treating the RHS as the answer, and re-applying the same set of rules for each reduction step. For example:

```
y x [a,b,x,c,d,e] ; A
= y x [b,x,c,d,e] ; by 1st rule ; B
= y x [x,c,d,e] ; by 1st rule ; C
= [x,c,d,e] ; by 2nd rule ; D
```

When we get to apply the 2nd rule, we arrive at the end of the reduction chain, i.e. we get our answer. The result of the Scheme call corresponding to `A`

will be the same as the Scheme call's corresponding to `B`

, or `C`

, or finally `D`

:

```
(y x (cons a (cons b (cons x z)))) ==
(y x (cons b (cons x z))) ==
(y x (cons x z)) ==
(cons x z)
```

What's so *mystic* about it, you ask? Here probably not much; but usually what that means is that by assuming the meaning of a function, and by interpreting the RHS through it, we arrive at the meaning of the LHS; and if this is the same meaning, *that* is our proof for it. *Induction* is kind of magical. For more involved examples see How to recursively reverse a list using only basic operations?.

Incidentally structural recursion is also known as *folding*, so your function is really

```
y s lis = para (λ (xs x r) (if (equal? x s) xs (r))) '() lis
```

using one type of folding, *paramorphism*, with explicit laziness,

```
para f z lis = g lis
where
g xs = z , if (null? xs)
= f xs (car xs) (λ () (g (cdr xs))) , otherwise
```

`()`

instead of`#f`

when the searched item is not found, this function is identical to the standard`member`

function. In other words, you can define this function thus:`(define (y s lis) (or (member s lis) '()))`

;-) – Chris Jester-Young Nov 30 '13 at 2:37