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What is the exclusive or functions in scheme? I've tried xor and ^, but both give me an unbound local variable error.

Googling found nothing.

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Do you want bitwise exclusive or? –  Brian Dec 18 '09 at 22:02
    
I'm working with specifically boolean (#t and #f), so as long as it acts properly on boolean, I'm good –  Jeffrey Aylesworth Dec 18 '09 at 22:23
    
Actually, I guess not equals works in this case, but I can't figure out what that is either? I tried != and /= –  Jeffrey Aylesworth Dec 18 '09 at 22:23

9 Answers 9

up vote 8 down vote accepted

I suggest you use (not (equal? foo bar)) if not equals works. Please note that there may be faster comparators for your situiation such as eq?

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So Scheme doesn't provide a not equal to function? You have to roll your own with not and (=|eq?|equal?)? –  Jeffrey Aylesworth Dec 18 '09 at 22:33
5  
Scheme is a fairly minimalist language. From R<sup>5</sup>RS: "Programming languages should be designed not by piling feature on top of feature, but by removing the weaknesses and restrictions that make additional features appear necessary." So, there are a lot of things provided by other languages that Scheme merely provides building blocks for. Any given Scheme implementation may provide a more complete library, and the SRFIs srfi.schemers.org help standardize a few of the extensions to the core language. –  Brian Campbell Dec 19 '09 at 7:54
    
Okay, thank you –  Jeffrey Aylesworth Dec 19 '09 at 13:35

If you mean bitwise xor of two integers, then each Scheme has it's own name (if any) since it's not in any standard. For example, PLT has these bitwise functions, including bitwise-xor.

(Uh, if you talk about booleans, then yes, not & or are it...)

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As far as I can tell from the R6RS (the latest definition of scheme), there is no pre-defined exclusive-or operation. However, xor is equivalent to not equals for boolean values so it's really quite easy to define on your own if there isn't a builtin function for it.

Assuming the arguments are restricted to the scheme booleans values #f and #t,

(define (xor a b)
  (not (boolean=? a b)))

will do the job.

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Kind of a different style of answer:

(define xor
  (lambda (a b)
    (cond
      (a (not b))
      (else b))))   
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Reading SRFI-1 shed a new light upon my answer. Forget efficiency and simplicity concerns or even testing! This beauty does it all:

(define (xor . args)
  (odd? (count (lambda (x) (eqv? x #t)) args)))

Or if you prefer:

(define (true? x) (eqv? x #t))
(define (xor . args) (odd? (count true? args)))
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Since xor could be used with any number of arguments, the only requirement is that the number of true occurences be odd. It could be defined roughly this way:

(define (true? x) (eqv? x #t))

(define (xor . args)
  (odd? (length (filter true? args))))

No argument checking needs to be done since any number of arguments (including none) will return the right answer.

However, this simple implementation has efficiency problems: both length and filter traverse the list twice; so I thought I could remove both and also the other useless predicate procedure "true?".

The value odd? receives is the value of the accumulator (aka acc) when args has no remaining true-evaluating members. If true-evaluating members exist, repeat with acc+1 and the rest of the args starting at the next true value or evaluate to false, which will cause acc to be returned with the last count.

(define (xor . args)
  (odd? (let count ([args (memv #t args)]
                    [acc 0])
          (if args
              (count (memv #t (cdr args))
                     (+ acc 1))
              acc))))
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> (define (xor a b)(not (equal? (and a #t)(and b #t))))
> (xor 'hello 'world)
$9 = #f
> (xor #f #f)
$10 = #f
> (xor (> 1 100)(< 1 100))
$11 = #t
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(define (xor a b)
  (and 
   (not (and a b))
   (or a b)))
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I revised my code recently because I needed 'xor in scheme and found out it wasn't good enough...

First, my earlier definition of 'true? made the assumption that arguments had been tested under a boolean operation. So I change:

(define (true? x) (eqv? #t))

... for:

(define (true? x) (not (eqv? x #f)))

... which is more like the "true" definition of 'true? However, since 'xor returns #t if its arguments have an 'odd? number of "true" arguments, testing for an even number of false cases is equivalent. So here's my revised 'xor:

(define (xor . args)
  (even? (count (lambda (x) (eqv? x #f)) args)))
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