In my day instead of
(loop for a in l appending (g a)) we wrote
(mapcan #'g l). Which is equivalent to
(apply #'append (mapcar #'g l)), more or less:
(defun flatten (l) (if l (if (atom l) (list l) (mapcan #'flatten l))))
So what does it mean in this case? Imagine you call
(flatten (list 1 2 3 4 5)). Each atom in your list gets enclosed in a list - becomes a singleton list, like
(1) (2) etc. Then they all are appended together, giving us back ... the original list:
( 1 2 3 4 5 )
( (1) (2) (3) (4) (5) )
( 1 2 3 4 5 )
So flattening a list of atoms is an
id operation (in Common LISP, that's
#'identity). Now imagine flattening a list which has atoms in it, and also a list of atoms. Again, each element of the list gets transformed by
flatten and then they are all appended together. A list of atoms stays as itself, as we just saw. Atoms get enclosed each in a list. So appending will give us back all the atoms that were on two levels in the nested list, now flattened:
( 11 12 (1 2 3 4) 13 )
( (11) (12) (1 2 3 4) (13) )
( 11 12 1 2 3 4 13 )
And so on and so forth, for more levels of nesting as well.
NILs as elements in lists pose a problem.
NIL is an empty list, and empty list contains nothing, so should not contribute anything. But
NIL is also an atom. So we make a special case for it, to not enclose it in a singleton list - leave it as it is, so when appended, it'll just disappear.