`destructuring-bind`

combines destructors with binding. A destructor is a function that lets you access a part of a data structure. `car`

and `cdr`

are simple destructors to extract the head and tail of a list. `getf`

is a general destructor framework. Binding is most commonly performed by `let`

. In this example, `fns`

is `(#'list #'round #'sqrt)`

(the arguments to `compose`

), so `(reverse fns)`

is `(#'sqrt #'round #'list)`

. Then

```
(destructuring-bind (fn1 . rest) '(#'sqrt #'round #'list)
...)
```

is equivalent to

```
(let ((tmp '(#'sqrt #'round #'list)))
(let ((fn1 (car tmp))
(rest (cdr tmp)))
...))
```

except that it doesn't bind `tmp`

, of course. The idea of `destructuring-bind`

is that it's a pattern matching construct: its first argument is a pattern that the data must match, and symbols in the pattern are bound to the corresponding pieces of the data.

So now `fn1`

is `#'sqrt`

and `rest`

is `(#'round #'list)`

. The `compose`

function returns a function: `(lambda (&rest args) ...)`

. Now consider what happens when you apply *that* function to some argument such as `4`

. The lambda can be applied, yielding

```
(reduce #'(lambda (v f) (funcall f v))
'(#'round #'list)
:initial-value (apply #'sqrt 4)))
```

The `apply`

function applies `fn1`

to the argument; since this argument is not a list, this is just `(#'sqrt 4)`

which is `2`

. In other words, we have

```
(reduce #'(lambda (v f) (funcall f v))
'(#'round #'list)
:initial-value 2)
```

Now the `reduce`

function does its job, which is to apply `#'(lambda (v f) (funcall f v))`

successively to the `#'round`

and to `#'list`

, starting with `2`

. This is equivalent to

```
(funcall #'list (funcall #'round 2))
→ (#'list (#'round 2))
→ '(2)
```