I want to use the function in a scheme program im writing however im unsure ho to translate the T & Nil values within the function. Can nil essentially be written as '() in scheme?

(define (listword (lambda (word)
    ((isvowel (car word)) (novowel word))
    (T (novowel word NIL))))))
  • 1
    Notice that Scheme is also a Lisp. Feb 24 '17 at 2:44

To avoid confusion I'll take Common Lisp as an exemplar of a 'traditional' Lisp and call it 'Lisp' below, as opposed to Scheme: Scheme is also a Lisp of course but I want to have to type less.

Both Lisp and Scheme use the common convention that there is a single distinguished false object with everything else being true. In the construction of lists, both Lisp and Scheme also need to have a special distinguished 'empty list' element which is also unique. Lisp then chooses to pun, making the empty list and false be the same object: Scheme does not, and treats them as distinct. Additionally, Lisp provides a name for the empty list object, while Scheme does not, and Scheme also does not treat the empty list object as self-evaluating while Lisp does. Both languages provide a canonical true object as well, but again Lisp provides a name for it while Scheme doesn't. In both languages the true and false objects are self-evaluating.


(Common) Lisp:

  • all objects are true except for the empty list, () -- (if () 1 2) evaluates to 2;
  • the empty list is self-evaluating -- (eq '() ()) is true;
  • the empty list is unique -- (eq () ()) and (eq () '()) are both true, as is (eq () (cdr (list 1))) for instance;
  • the empty list has a name, NIL -- (eq nil ()) & so on;
  • there is a canonical true object whose name is T and whose value is T;
  • while it is perhaps disputed, I think it is better to use NIL when you want to talk about false and () when you want to talk about the empty list.


  • all objects are true except for the special false object which is #f -- (if #f 1 2) evaluates to 2 while (if x 1 2) evaluates to 1 for x having any value not eq? to #f;
  • #f is self-evaluating --(eq? #f '#f) is true;
  • #f is unique;
  • #f has no special name in the sense that there is no symbol whose value it is (this is probably not the right terminology in Scheme);
  • there is a canonical true object, #t, although all objects are true other than #f;
  • there is a unique empty list object, () -- this object is not the same as #f, is not self-evaluating and does not have a name, so (eq? #f '()) is false, but (eq? '() '()) is true, as is (eq? '() (cdr (list 1))), while (if '() 1 2) evaluates to 1 and (eq? () 1) is an error.

Disclaimer: my knowledge of CL is better than my knowledge of Scheme.


In Common Lisp nil/'nil/()/'() represents the same value nil and it is both the empty list and the one false value. In Scheme they are two different values, '() for the empty list and #f as the false value. When translating Common Lisp one needs to determine if the value represents a false value or an empty list. In some cases you will have the empty list being used as a boolean and thus you would need to do (not (null? v)) where CL just does v. The reason for this is that only #f is false in Scheme and thus the empty list is a true value. (if '() #t #f) ; ==> #t

In Common Lisp t can be replaced by #t, but in Scheme there are special symbols in some forms like else in cond that is the idiomatic way to do the alternative term.


I guess you're translating some Common Lisp code to Scheme. In Scheme, the T at the end of a cond expression can be replaced by true, but the idiomatic way is to use an else. And NIL is just the empty list '(), sometimes aliased as null.

Also, be careful with how you define a procedure, you wrote an incorrect opening parenthesis in the first line - the correct way is:

(define listword
  (lambda (word)

Or equivalently (and perhaps more idiomatic):

(define (listword word)

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