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I've been trying to find a way to condense nested lists into numbers that go back in the original list, but I having some trouble.

I've been looking at the flatten function (that is so widely available) which is given here:

(defun flatten (l)
    ((null l) nil)
    ((atom l) (list l))
    (t (loop for a in l appending (flatten a)))))

I understand this example is recursion, but how does it work? It check if the element is null or an atom, but what does it do if the element falls into these conditions?

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3 Answers 3

up vote 1 down vote accepted

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.

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APPLY is not a good idea, since it does not work on arbitrarily long lists. –  Rainer Joswig May 5 '12 at 21:10
@RainerJoswig just used it for illustration. –  Will Ness May 5 '12 at 21:11
With the other answers of how the code executes and with Will Ness's explanation of the logic behind this program (which I wouldn't have gotten otherwise), I understand this concept now! –  Zchpyvr May 5 '12 at 22:12
@Zchpyvr great! now you should pick one of the answers and "accept" it - click on the big outline V sign next to an answer, to turn it into a big green V sign. :) Until you've done that, people will assume your issue is still unresolved. –  Will Ness May 6 '12 at 6:53
@OpenLearner: CALL-ARGUMENTS-LIMIT can be as low as 50. Use REDUCE or something else... –  Rainer Joswig Nov 14 '13 at 12:20
(defun flatten (l)

Above defines a function FLATTEN with one argument called L.



    ((null l) nil)

the value of the argument L is the empty list, return the empty list.

    ((atom l) (list l))

or if the argument L is an atom (i.e. not a list), then return a list with the atom as its only item.


or else we have a non-empty list

       (loop for a in l

then loop through all the items in the list which is the value of L

        appending (flatten a)

and append the results of flattening each list item.

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Is appending a keyword? –  Zchpyvr May 5 '12 at 22:17
@Zchpyvr: APPENDING is a feature of the LOOP macro. lispworks.com/documentation/HyperSpec/Body/06_ac.htm –  Rainer Joswig May 5 '12 at 22:24
  1. If the element you are looking at is nil - it is the end of the list, return nil.

  2. If the element you are looking at is not a list return a list containing that element (I'm not actually sure this is a right thing to do, because given an atom, which is not a list, it would return a list with the atom, rather then the atom itself).

  3. Otherwise (if it is a list), loop through all elements of it and append all the flattened sub-trees, (which you flattened by calling flatten), then return them.

This is short, but not the most efficient algorithm since append needs to go all the way to the end of the list in order to cons one part on the tail of another part. Below is slightly more convoluted, but looks like more efficient version of it:

(defun flatten (x &optional y)
    ((null x)
       ((null y) nil)
       ((listp (car y))
        (flatten (car y) (cdr y)))
       (t (cons (car y) (flatten (cdr y))))))
    ((listp (car x))
     (flatten (car x) (if y (list (cdr x) y) (cdr x))))
    (t (cons (car x) (flatten (cdr x) y)))))

The algorithm behind this function does something as follows:

  1. If we have neither first element, nor the rest - we did everything, so just return nil (end of the list).

  2. If there's no first element - split the second into the first and the rest and repeat.

  3. If there is the first element, cons it into the list, if there is a second element - keep it, otherwise, select the next element and repeat.

EDIT: I changed the #3, because the interpretation was really vague / could be wrong.

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sorry, you explanation is incorrect, esp. point #3. –  Will Ness May 5 '12 at 20:56
no I mean explanation at the start of your answer. the words aren't exactly correct, IMO. the results of flattening each element of list are all appended together, is what's done by the OP code. I thought you were describing the code as written in the question. –  Will Ness May 5 '12 at 21:06
Even after staring at your efficient flatten function for a long time.... I still don't get it. I'm a greenhorn at lisp, but I'll come back at this code another day and understand your concept. Thanks! –  Zchpyvr May 5 '12 at 22:22
your code is linear-recursive instead of tree-recursive; but on implementations without TCO % cons (is there any, at all?..) it's still a full-blown recursion. Plus, it conses a lot too, recreating its input structure anew. It is possible to fix both problems in one step. Here's one example how. :) –  Will Ness May 6 '12 at 7:21
I think mapcan won't perform any extra traversals, and I'd expect (loop for a in l nconcing (g a)) to not do any either. The maximal recursion depth for both is the nesting depth, but for your version, which replaces looping with recursion, it will be the length of the flattened list. Even without reusing the old structure (which has its place, just should be clearly marked with e.g. nflatten name) there's benefits to re-writing the TCO%cons code such as yours, as a loop instead of recursion, e.g. w/ do construct, building the result list in top-down manner (to avoid reverse). –  Will Ness May 8 '12 at 5:54

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