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I need to find how many elements a given input has. the input can be a list or a symbol, for example:

  • 'a => 1 element
  • '(3 . 4) => 2 elements
  • '(a b . c) => 3 elements
  • '((a b . c) 3 . 4) => 5 elements

one problem is that when I'm going through the input, every element can be a list of its own, or a pair (just started learning scheme, so my tools for right now are mainly car/cdr), so, when should I stop my loop? when if (null? x) condition is true? or maybe when if (null? (car x)) is true?

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2 Answers 2

up vote 2 down vote accepted

The title of your question should be changes to how to count atoms in a list structure. There are numerous questions on SE about it. Here is how:

  1. if element is a pair, the result would be the sum of the car and the cdr applied to the same procedure.
  2. else the length is 1


Here's the above algorithm as code:

(define (count-all-atoms x)
  (if (pair? x)
      (+ (count-all-atoms (car x))
         (count-all-atoms (cdr x)))

To comment the comments I've got there are actually 2 more ways to implement this and all of them will give the correct answer to OP's examples. It all has to do with how we interpret () to be.

Depending on '(()) should be counted as 0, 1 or 2 elements. Zero since it's all lists without any atoms, 1 since its one list with one null element (not counting null terminator) or 2 since it's the same as a dotted pair with two null elements ((() ())). It's the last one that my text described, but here are the two other ways:

;; count (()) and () as 0
;; no nil value is counted as it is a list without elements
(define (count-non-nil-atoms x)
  (if (pair? x) 
      (+ (count-non-nil-atoms (car x)) 
         (count-non-nil-atoms (cdr x)))
      (if (null? x)

;; count (()) as 1 and () as 0
;; ie. count only nil as atom in car position but not as a list terminator
;; probably most common
(define (count-atoms x)
  (if (pair? x)
      (let ((a (car x)) (d (cdr x)))        
        (+  (if (null? a) 1 (count-atoms a))
            (count-atoms d)))
      (if (null? x) 0 1)))
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Step 0: if the element is the end of list, the length is 0. –  Chris Jester-Young Mar 10 '14 at 13:10
@Sylwester thank you very much! I tried do so before, but maybe I needed someone to write it down for me :) –  omi Mar 10 '14 at 13:58
@ChrisJester-Young That's actually an interesting question. nil, which is the same as () in Common Lisp`, is an atom, so it might be considered an "atom in a list structure", especially given the example in the question where there are improper lists that are terminated with non-nil atoms. –  Joshua Taylor Mar 10 '14 at 17:09
@JoshuaTaylor Since the examples by OP avoids the problem I think the naive counting everything not pair as good here. Anyway I updated with the 3 possible ways I could think of. –  Sylwester Mar 10 '14 at 20:57
@Sylwester Right; I think the original description (where nil would be counted as 1 makes sense here. I'm not convinced that there should be a "tep 0: if the element is the end of list, the length is 0.". –  Joshua Taylor Mar 10 '14 at 21:30

In Common Lisp, an atom is anything that isn't a pair, and you can check whether something is an atom with the atom function. If something is not an atom, then it's a pair, which means that you can call car and cdr with it to retrieve the parts of the pair. A simple solution to this, then, is simply:

(defun count-atoms (object)
  (if (atom object) 1
      (+ (count-atoms (car object))
         (count-atoms (cdr object)))))

Note that this counts the nil terminator of a proper list, so

(a b . c)   ;=> 3
(a b . nil) ;=> 3, even though (a b . nil) == (a b)

but this seems to be in line with your description of counting atoms, rather than elements in a list. This implementation does consume stack space, though, so you might have problems with very large structures. You might use a continuation passing approach instead that a Lisp implementation that supports tail call optimization could do with constant stack space:

(defun count-atoms (object)
  (labels ((kount (object k)
             (if (atom object)
                 (funcall k 1)
                 (kount (car object)
                        (lambda (l)
                          (kount (cdr object)
                                 (lambda (r)
                                   (funcall k (+ l r)))))))))
    (kount object 'identity)))

That continuation passing style avoids using lots of stack space (if the implementation optimizes tail calls), but its not all that transparent (unless you're very accustomed to that style). We can use an explicit stack and a loop to get something that's much more likely to use constant stack space:

(defun count-atoms (object)
  (do ((objects (list object)) (natoms 0))
      ((endp objects) natoms)
    (let ((object (pop objects)))
        ((atom object) (incf natoms))
        (t (push (car object) objects)
           (push (cdr object) objects))))))

Now that we have it as a do loop, it's easy to see how we might write it using tail recursion (what you'd probably do if you were working in Scheme):

(defun count-atoms (object)
  (labels ((kount (objects natoms)
               ((endp objects)
               ((atom (first objects))
                (kount (rest objects) (1+ natoms)))
                (kount (list* (car (first objects))
                              (cdr (first objects))
                              (rest objects))
    (kount (list object) 0)))
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1+ I'd expect fancy loop version rather than CPS to make it iterative in CL :) –  Sylwester Mar 10 '14 at 21:07
@Sylwester well, loop is great for things that only require one value for storing iteration state (e.g., an index into an array, or a cons (whose cdr is the implicit next in a list). I'm not sure if loop would help here, since there really is a stack of "stuff left to do". I mean, yes, we could hold a stack manually, but that's a bit different, I suppose (but a nice enough solution that I'll add one in). –  Joshua Taylor Mar 10 '14 at 21:14

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