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I am trying to learn Common Lisp with the book Common Lisp: A gentle introduction to Symbolic Computation. In addition, I am using SBCL, Emacs and Slime.

In chapter 7, the author suggests there are three styles of programming the book will cover: recursion, iteration and applicative programming.

I am interested on the last one. This style is famous for the applicative operator funcall which is the primitive responsible for other applicative operators such as mapcar.

Thus, with an educational purpose, I decided to implement my own version of mapcar using funcall:

(defun my-mapcar (fn xs)
  (if (null xs)
      nil
      (cons (funcall fn (car xs))
            (my-mapcar fn (cdr xs)))))

As you might see, I used recursion as a programming style to build an iconic applicative programming function.

It seems to work:

CL-USER> (my-mapcar (lambda (n) (+ n 1)) (list 1 2 3 4))
(2 3 4 5)

CL-USER> (my-mapcar (lambda (n) (+ n 1)) (list ))
NIL

;; comparing the results with the official one

CL-USER> (mapcar (lambda (n) (+ n 1)) (list ))
NIL

CL-USER> (mapcar (lambda (n) (+ n 1)) (list 1 2 3 4))
(2 3 4 5)

Is there a way to implement mapcar without using recursion or iteration? Using only applicative programming as a style?

Thanks.

Obs.: I tried to see how it was implemented. But it was not possible

CL-USER> (function-lambda-expression #'mapcar)
NIL
T
MAPCAR

I also used Emacs M-. to look for the documentation. However, the points below did not help me. I used this to find the files below:

/usr/share/sbcl-source/src/code/list.lisp
  (DEFUN MAPCAR)
/usr/share/sbcl-source/src/compiler/seqtran.lisp
  (:DEFINE-SOURCE-TRANSFORM MAPCAR)
/usr/share/sbcl-source/src/compiler/fndb.lisp
  (DECLAIM MAPCAR SB-C:DEFKNOWN)
2
  • 1
    When you get a list of files for inspection in Slime (which you can also do by placing the cursor on the item of interest, e.g., mapcar, and pressing M-.), you can view any one of them by moving the cursor the the line of interest (e.g., (:DEFINE-SOURCE-TRANSFORM MAPCAR)). If you do that, you will see that the function mapfoo-transform may be of some interest, so press M-. on that. I discussed this process in the answer I linked to under your previous question. May 21, 2021 at 16:33
  • Hi, thanks for helping again :). I actually used M-. to get the info above. It was M-x on my text but that was a typo. I am checking out mapfoo-transform too. Thanks. May 21, 2021 at 16:42

3 Answers 3

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mapcar is by itself a primitive applicative operator (pag. 220 of Common Lisp: A gentle introduction to Symbolic Computation). So, if you want to rewrite it in an applicative way, you should use some other primitive applicative operator, for instance map or map-into. For instance, with map-into:

CL-USER> (defun my-mapcar (fn list &rest lists)
           (apply #'map-into (make-list (length list)) fn list lists))
MY-MAPCAR
CL-USER> (my-mapcar #'1+ '(1 2 3))
(2 3 4)
CL-USER> (my-mapcar #'+ '(1 2 3) '(10 20 30) '(100 200 300))
(111 222 333)
2

Technically, recursion can be implemented as follows:

(defun fix (f)
   (funcall (lambda (x) (funcall x x))
            (lambda (x) (funcall f (lambda (&rest y) (apply (funcall x x) y))))))

Notice that fix does not use recursion in any way. In fact, we could have only used lambda in the definition of f as follows:

(defconstant fix-combinator 
             (lambda (g) (funcall 
                          (lambda (x) (funcall x x))
                          (lambda (x) (funcall 
                                       g 
                                       (lambda (&rest y) (apply (funcall x x) 
                                                                 y)))))))

(defun fix-2 (f)
  (funcall fix-combinator f))

The fix-combinator constant is more commonly known as the y combinator.

It turns out that fix has the following property:

Evaluating (apply (fix f) list) is equivalent to evaluating (apply (funcall f (fix f)) list). Informally, we have (fix f) = (funcall f (fix f)).

Thus, we can define map-car (I'm using a different name to avoid package lock) by

(defun map-car (func lst)
  (funcall (fix (lambda (map-func) (lambda (lst) ; We want mapfunc to be (lambda (lst) (mapcar func lst))
    (if (endp lst) 
        nil 
        (cons (funcall func (car lst)) 
              (funcall map-func (cdr lst)))))))
    lst))

Note the lack of recursion or iteration.

That being said, generally mapcar is just taken as a primitive notion when using the "applicative" style of programming.

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Another way you can implement mapcar is by using the more general reduce function (a.k.a. fold). Let's name the user-provided function f and define my-mapcar.

The reduce function carries an accumulator value that builds up the resulting list, here it is going take a value v, a sublist rest, and call cons with (funcall f v) and rest, so as to build a list.

More precisely, here reduce is going to implement a right-fold, since cons is right-associative (e.g. the recursive list is the "right" hand side, ie. the second argument of cons, e.g. (cons a (cons b (cons nil)))).

In order to define a right-fold with reduce, you pass :from-end t, which indicates that it builds-up a value from the last element and the initial accumulator to obtain a new accumulator value, then the second to last element with that new accumulator to build a new accumulator, etc. This is how you ensure that the resulting elements are in the same order as the input list.

In that case, the reducing function takes its the current element as its first argument, and the accumulator as a second argument.

Since the type of the elements and the type of the accumulator are different, you need to pass an :initial-value for the accumulator (the default behavior where the initial-value is taken from the list is for functions like + or *, where the accumulator is in the same domain as the list elements).

With that in mind, you can write it as follows:

(defun my-map (f list)
  (reduce (lambda (v rest) (cons (funcall f v) rest))
          list
          :from-end t
          :initial-value nil))

For example:

(my-map #'prin1-to-string '(0 1 2 3))
; => ("0" "1" "2" "3")

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