## Main problem with `loop`

There are a few problems here. First, you can write the loop as the following. There are `return-from`

and `while`

forms in Common Lisp, but `loop`

defines its own little language that also recognizes `while`

and `return`

, so you can just use those:

```
(loop for x in list
when (equalp maxlen (list-length x))
return x)
```

A loop like this can actually be written more concisely with `find`

though. It's just

```
(find maxlen list :key list-length :test 'equalp)
```

Note, however, that `list-length`

should always return a number or `nil`

, so `equalp`

is overkill. You can just use `eql`

, and that's the default for `find`

, so you can even write

```
(find maxlen list :key list-length)
```

`list-length`

and `maximize`

`list-length`

is a lot like `length`

, except that if a list has circular structure, it returns `nil`

, whereas it's an error to call `length`

with an improper list. But if you're using `(loop ... maximize ...)`

, you can't have `nil`

values, so the only case that `list-length`

handles that `length`

wouldn't is one that will still give you an error. E.g.,

```
CL-USER> (loop for x in '(4 3 nil) maximize x)
; Evaluation aborted on #<TYPE-ERROR expected-type: REAL datum: NIL>.
```

(Actually, `length`

works with other types of sequences too, so `list-length`

would error if you passed a vector, but `length`

wouldn't.) So, if you know that they're all proper lists, you can just

```
(loop for x in list
maximizing (length x))
```

If they're not all necessarily proper lists (so that you do need `list-length`

), then you need to guard like:

```
(loop for x in list
for len = (list-length x)
unless (null len) maximize len)
```

## A more efficient argmax

However, right now you're making two passes over the list, and you're computing the length of each sublist twice. Once is when you compute the maximum length, and the other is when you go to find one with the maximum value. If you do this in one pass, you'll save time. `argmax`

doesn't have an obvious elegant solution, but here are implementations based on `reduce`

, `loop`

, and `do*`

.

```
(defun argmax (fn list &key (predicate '>) (key 'identity))
(destructuring-bind (first &rest rest) list
(car (reduce (lambda (maxxv x)
(destructuring-bind (maxx . maxv) maxxv
(declare (ignore maxx))
(let ((v (funcall fn (funcall key x))))
(if (funcall predicate v maxv)
(cons x v)
maxxv))))
rest
:initial-value (cons first (funcall fn (funcall key first)))))))
```

```
(defun argmax (function list &key (predicate '>) (key 'identity))
(loop
for x in list
for v = (funcall function (funcall key x))
for maxx = x then maxx
for maxv = v then maxv
when (funcall predicate v maxv)
do (setq maxx x
maxv v)
finally (return maxx)))
```

```
(defun argmax (function list &key (predicate '>) (key 'identity))
(do* ((x (pop list)
(pop list))
(v (funcall function (funcall key x))
(funcall function (funcall key x)))
(maxx x)
(maxv v))
((endp list) maxx)
(when (funcall predicate v maxv)
(setq maxx x
maxv v))))
```

They produce the same results:

```
CL-USER> (argmax 'length '((1 2 3) (4 5) (6 7 8 9)))
(6 7 8 9)
CL-USER> (argmax 'length '((1 2 3) (6 7 8 9) (4 5)))
(6 7 8 9)
CL-USER> (argmax 'length '((6 7 8 9) (1 2 3) (4 5)))
(6 7 8 9)
```