mirror of
git://git.gnupg.org/gnupg.git
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bce02a8b0f
* tests/gpgscm/init.scm (throw'): Make it impossible to catch '*interpreter-exit*'. This fixes 'exit' (and with it 'fail') inside 'catch' statements. Signed-off-by: Justus Winter <justus@g10code.com>
824 lines
26 KiB
Scheme
824 lines
26 KiB
Scheme
; Initialization file for TinySCHEME 1.41
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; Per R5RS, up to four deep compositions should be defined
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(define (caar x) (car (car x)))
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(define (cadr x) (car (cdr x)))
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(define (cdar x) (cdr (car x)))
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(define (cddr x) (cdr (cdr x)))
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(define (caaar x) (car (car (car x))))
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(define (caadr x) (car (car (cdr x))))
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(define (cadar x) (car (cdr (car x))))
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(define (caddr x) (car (cdr (cdr x))))
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(define (cdaar x) (cdr (car (car x))))
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(define (cdadr x) (cdr (car (cdr x))))
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(define (cddar x) (cdr (cdr (car x))))
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(define (cdddr x) (cdr (cdr (cdr x))))
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(define (caaaar x) (car (car (car (car x)))))
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(define (caaadr x) (car (car (car (cdr x)))))
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(define (caadar x) (car (car (cdr (car x)))))
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(define (caaddr x) (car (car (cdr (cdr x)))))
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(define (cadaar x) (car (cdr (car (car x)))))
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(define (cadadr x) (car (cdr (car (cdr x)))))
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(define (caddar x) (car (cdr (cdr (car x)))))
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(define (cadddr x) (car (cdr (cdr (cdr x)))))
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(define (cdaaar x) (cdr (car (car (car x)))))
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(define (cdaadr x) (cdr (car (car (cdr x)))))
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(define (cdadar x) (cdr (car (cdr (car x)))))
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(define (cdaddr x) (cdr (car (cdr (cdr x)))))
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(define (cddaar x) (cdr (cdr (car (car x)))))
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(define (cddadr x) (cdr (cdr (car (cdr x)))))
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(define (cdddar x) (cdr (cdr (cdr (car x)))))
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(define (cddddr x) (cdr (cdr (cdr (cdr x)))))
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;;;; Utility to ease macro creation
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(define (macro-expand form)
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((eval (get-closure-code (eval (car form)))) form))
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(define (macro-expand-all form)
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(if (macro? form)
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(macro-expand-all (macro-expand form))
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form))
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(define *compile-hook* macro-expand-all)
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(macro (unless form)
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`(if (not ,(cadr form)) (begin ,@(cddr form))))
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(macro (when form)
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`(if ,(cadr form) (begin ,@(cddr form))))
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; DEFINE-MACRO Contributed by Andy Gaynor
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(macro (define-macro dform)
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(if (symbol? (cadr dform))
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`(macro ,@(cdr dform))
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(let ((form (gensym)))
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`(macro (,(caadr dform) ,form)
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(apply (lambda ,(cdadr dform) ,@(cddr dform)) (cdr ,form))))))
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; Utilities for math. Notice that inexact->exact is primitive,
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; but exact->inexact is not.
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(define exact? integer?)
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(define (inexact? x) (and (real? x) (not (integer? x))))
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(define (even? n) (= (remainder n 2) 0))
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(define (odd? n) (not (= (remainder n 2) 0)))
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(define (zero? n) (= n 0))
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(define (positive? n) (> n 0))
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(define (negative? n) (< n 0))
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(define complex? number?)
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(define rational? real?)
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(define (abs n) (if (>= n 0) n (- n)))
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(define (exact->inexact n) (* n 1.0))
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(define (<> n1 n2) (not (= n1 n2)))
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; min and max must return inexact if any arg is inexact; use (+ n 0.0)
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(define (max . lst)
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(foldr (lambda (a b)
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(if (> a b)
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(if (exact? b) a (+ a 0.0))
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(if (exact? a) b (+ b 0.0))))
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(car lst) (cdr lst)))
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(define (min . lst)
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(foldr (lambda (a b)
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(if (< a b)
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(if (exact? b) a (+ a 0.0))
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(if (exact? a) b (+ b 0.0))))
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(car lst) (cdr lst)))
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(define (succ x) (+ x 1))
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(define (pred x) (- x 1))
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(define gcd
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(lambda a
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(if (null? a)
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0
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(let ((aa (abs (car a)))
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(bb (abs (cadr a))))
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(if (= bb 0)
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aa
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(gcd bb (remainder aa bb)))))))
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(define lcm
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(lambda a
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(if (null? a)
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1
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(let ((aa (abs (car a)))
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(bb (abs (cadr a))))
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(if (or (= aa 0) (= bb 0))
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0
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(abs (* (quotient aa (gcd aa bb)) bb)))))))
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(define (string . charlist)
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(list->string charlist))
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(define (list->string charlist)
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(let* ((len (length charlist))
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(newstr (make-string len))
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(fill-string!
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(lambda (str i len charlist)
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(if (= i len)
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str
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(begin (string-set! str i (car charlist))
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(fill-string! str (+ i 1) len (cdr charlist)))))))
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(fill-string! newstr 0 len charlist)))
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(define (string-fill! s e)
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(let ((n (string-length s)))
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(let loop ((i 0))
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(if (= i n)
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s
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(begin (string-set! s i e) (loop (succ i)))))))
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(define (string->list s)
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(let loop ((n (pred (string-length s))) (l '()))
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(if (= n -1)
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l
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(loop (pred n) (cons (string-ref s n) l)))))
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(define (string-copy str)
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(string-append str))
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(define (string->anyatom str pred)
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(let* ((a (string->atom str)))
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(if (pred a) a
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(error "string->xxx: not a xxx" a))))
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(define (string->number str . base)
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(let ((n (string->atom str (if (null? base) 10 (car base)))))
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(if (number? n) n #f)))
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(define (anyatom->string n pred)
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(if (pred n)
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(atom->string n)
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(error "xxx->string: not a xxx" n)))
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(define (number->string n . base)
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(atom->string n (if (null? base) 10 (car base))))
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(define (char-cmp? cmp a b)
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(cmp (char->integer a) (char->integer b)))
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(define (char-ci-cmp? cmp a b)
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(cmp (char->integer (char-downcase a)) (char->integer (char-downcase b))))
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(define (char=? a b) (char-cmp? = a b))
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(define (char<? a b) (char-cmp? < a b))
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(define (char>? a b) (char-cmp? > a b))
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(define (char<=? a b) (char-cmp? <= a b))
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(define (char>=? a b) (char-cmp? >= a b))
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(define (char-ci=? a b) (char-ci-cmp? = a b))
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(define (char-ci<? a b) (char-ci-cmp? < a b))
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(define (char-ci>? a b) (char-ci-cmp? > a b))
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(define (char-ci<=? a b) (char-ci-cmp? <= a b))
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(define (char-ci>=? a b) (char-ci-cmp? >= a b))
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; Note the trick of returning (cmp x y)
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(define (string-cmp? chcmp cmp a b)
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(let ((na (string-length a)) (nb (string-length b)))
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(let loop ((i 0))
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(cond
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((= i na)
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(if (= i nb) (cmp 0 0) (cmp 0 1)))
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((= i nb)
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(cmp 1 0))
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((chcmp = (string-ref a i) (string-ref b i))
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(loop (succ i)))
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(else
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(chcmp cmp (string-ref a i) (string-ref b i)))))))
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(define (string=? a b) (string-cmp? char-cmp? = a b))
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(define (string<? a b) (string-cmp? char-cmp? < a b))
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(define (string>? a b) (string-cmp? char-cmp? > a b))
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(define (string<=? a b) (string-cmp? char-cmp? <= a b))
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(define (string>=? a b) (string-cmp? char-cmp? >= a b))
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(define (string-ci=? a b) (string-cmp? char-ci-cmp? = a b))
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(define (string-ci<? a b) (string-cmp? char-ci-cmp? < a b))
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(define (string-ci>? a b) (string-cmp? char-ci-cmp? > a b))
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(define (string-ci<=? a b) (string-cmp? char-ci-cmp? <= a b))
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(define (string-ci>=? a b) (string-cmp? char-ci-cmp? >= a b))
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(define (list . x) x)
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(define (foldr f x lst)
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(if (null? lst)
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x
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(foldr f (f x (car lst)) (cdr lst))))
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(define (unzip1-with-cdr . lists)
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(unzip1-with-cdr-iterative lists '() '()))
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(define (unzip1-with-cdr-iterative lists cars cdrs)
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(if (null? lists)
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(cons cars cdrs)
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(let ((car1 (caar lists))
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(cdr1 (cdar lists)))
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(unzip1-with-cdr-iterative
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(cdr lists)
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(append cars (list car1))
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(append cdrs (list cdr1))))))
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(define (map proc . lists)
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(if (null? lists)
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(apply proc)
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(if (null? (car lists))
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'()
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(let* ((unz (apply unzip1-with-cdr lists))
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(cars (car unz))
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(cdrs (cdr unz)))
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(cons (apply proc cars) (apply map (cons proc cdrs)))))))
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(define (for-each proc . lists)
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(if (null? lists)
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(apply proc)
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(if (null? (car lists))
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#t
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(let* ((unz (apply unzip1-with-cdr lists))
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(cars (car unz))
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(cdrs (cdr unz)))
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(apply proc cars) (apply map (cons proc cdrs))))))
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(define (list-tail x k)
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(if (zero? k)
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x
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(list-tail (cdr x) (- k 1))))
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(define (list-ref x k)
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(car (list-tail x k)))
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(define (last-pair x)
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(if (pair? (cdr x))
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(last-pair (cdr x))
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x))
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(define (head stream) (car stream))
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(define (tail stream) (force (cdr stream)))
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(define (vector-equal? x y)
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(and (vector? x) (vector? y) (= (vector-length x) (vector-length y))
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(let ((n (vector-length x)))
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(let loop ((i 0))
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(if (= i n)
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#t
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(and (equal? (vector-ref x i) (vector-ref y i))
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(loop (succ i))))))))
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(define (list->vector x)
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(apply vector x))
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(define (vector-fill! v e)
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(let ((n (vector-length v)))
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(let loop ((i 0))
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(if (= i n)
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v
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(begin (vector-set! v i e) (loop (succ i)))))))
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(define (vector->list v)
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(let loop ((n (pred (vector-length v))) (l '()))
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(if (= n -1)
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l
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(loop (pred n) (cons (vector-ref v n) l)))))
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;; The following quasiquote macro is due to Eric S. Tiedemann.
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;; Copyright 1988 by Eric S. Tiedemann; all rights reserved.
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;;
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;; Subsequently modified to handle vectors: D. Souflis
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(macro
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quasiquote
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(lambda (l)
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(define (mcons f l r)
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(if (and (pair? r)
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(eq? (car r) 'quote)
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(eq? (car (cdr r)) (cdr f))
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(pair? l)
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(eq? (car l) 'quote)
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(eq? (car (cdr l)) (car f)))
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(if (or (procedure? f) (number? f) (string? f))
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f
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(list 'quote f))
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(if (eqv? l vector)
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(apply l (eval r))
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(list 'cons l r)
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)))
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(define (mappend f l r)
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(if (or (null? (cdr f))
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(and (pair? r)
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(eq? (car r) 'quote)
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(eq? (car (cdr r)) '())))
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l
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(list 'append l r)))
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(define (foo level form)
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(cond ((not (pair? form))
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(if (or (procedure? form) (number? form) (string? form))
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form
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(list 'quote form))
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)
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((eq? 'quasiquote (car form))
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(mcons form ''quasiquote (foo (+ level 1) (cdr form))))
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(#t (if (zero? level)
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(cond ((eq? (car form) 'unquote) (car (cdr form)))
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((eq? (car form) 'unquote-splicing)
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(error "Unquote-splicing wasn't in a list:"
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form))
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((and (pair? (car form))
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(eq? (car (car form)) 'unquote-splicing))
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(mappend form (car (cdr (car form)))
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(foo level (cdr form))))
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(#t (mcons form (foo level (car form))
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(foo level (cdr form)))))
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(cond ((eq? (car form) 'unquote)
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(mcons form ''unquote (foo (- level 1)
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(cdr form))))
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((eq? (car form) 'unquote-splicing)
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(mcons form ''unquote-splicing
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(foo (- level 1) (cdr form))))
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(#t (mcons form (foo level (car form))
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(foo level (cdr form)))))))))
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(foo 0 (car (cdr l)))))
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;;;;;Helper for the dynamic-wind definition. By Tom Breton (Tehom)
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(define (shared-tail x y)
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(let ((len-x (length x))
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(len-y (length y)))
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(define (shared-tail-helper x y)
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(if
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(eq? x y)
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x
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(shared-tail-helper (cdr x) (cdr y))))
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(cond
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((> len-x len-y)
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(shared-tail-helper
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(list-tail x (- len-x len-y))
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y))
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((< len-x len-y)
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(shared-tail-helper
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x
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(list-tail y (- len-y len-x))))
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(#t (shared-tail-helper x y)))))
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;;;;;Dynamic-wind by Tom Breton (Tehom)
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;;Guarded because we must only eval this once, because doing so
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;;redefines call/cc in terms of old call/cc
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(unless (defined? 'dynamic-wind)
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(let
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;;These functions are defined in the context of a private list of
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;;pairs of before/after procs.
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( (*active-windings* '())
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;;We'll define some functions into the larger environment, so
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;;we need to know it.
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(outer-env (current-environment)))
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;;Poor-man's structure operations
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(define before-func car)
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(define after-func cdr)
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(define make-winding cons)
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;;Manage active windings
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(define (activate-winding! new)
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((before-func new))
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(set! *active-windings* (cons new *active-windings*)))
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(define (deactivate-top-winding!)
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(let ((old-top (car *active-windings*)))
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;;Remove it from the list first so it's not active during its
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;;own exit.
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(set! *active-windings* (cdr *active-windings*))
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((after-func old-top))))
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(define (set-active-windings! new-ws)
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(unless (eq? new-ws *active-windings*)
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(let ((shared (shared-tail new-ws *active-windings*)))
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;;Define the looping functions.
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;;Exit the old list. Do deeper ones last. Don't do
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;;any shared ones.
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(define (pop-many)
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(unless (eq? *active-windings* shared)
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(deactivate-top-winding!)
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(pop-many)))
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;;Enter the new list. Do deeper ones first so that the
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;;deeper windings will already be active. Don't do any
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;;shared ones.
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(define (push-many new-ws)
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(unless (eq? new-ws shared)
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(push-many (cdr new-ws))
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(activate-winding! (car new-ws))))
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|
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;;Do it.
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(pop-many)
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(push-many new-ws))))
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|
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;;The definitions themselves.
|
||
(eval
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`(define call-with-current-continuation
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;;It internally uses the built-in call/cc, so capture it.
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,(let ((old-c/cc call-with-current-continuation))
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(lambda (func)
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;;Use old call/cc to get the continuation.
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(old-c/cc
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(lambda (continuation)
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;;Call func with not the continuation itself
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;;but a procedure that adjusts the active
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;;windings to what they were when we made
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;;this, and only then calls the
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;;continuation.
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||
(func
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(let ((current-ws *active-windings*))
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(lambda (x)
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(set-active-windings! current-ws)
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(continuation x)))))))))
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||
outer-env)
|
||
;;We can't just say "define (dynamic-wind before thunk after)"
|
||
;;because the lambda it's defined to lives in this environment,
|
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;;not in the global environment.
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||
(eval
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`(define dynamic-wind
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,(lambda (before thunk after)
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;;Make a new winding
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(activate-winding! (make-winding before after))
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(let ((result (thunk)))
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;;Get rid of the new winding.
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||
(deactivate-top-winding!)
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||
;;The return value is that of thunk.
|
||
result)))
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outer-env)))
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||
|
||
(define call/cc call-with-current-continuation)
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||
|
||
|
||
;;;;; atom? and equal? written by a.k
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||
|
||
;;;; atom?
|
||
(define (atom? x)
|
||
(not (pair? x)))
|
||
|
||
;;;; equal?
|
||
(define (equal? x y)
|
||
(cond
|
||
((pair? x)
|
||
(and (pair? y)
|
||
(equal? (car x) (car y))
|
||
(equal? (cdr x) (cdr y))))
|
||
((vector? x)
|
||
(and (vector? y) (vector-equal? x y)))
|
||
((string? x)
|
||
(and (string? y) (string=? x y)))
|
||
(else (eqv? x y))))
|
||
|
||
;;;; (do ((var init inc) ...) (endtest result ...) body ...)
|
||
;;
|
||
(macro do
|
||
(lambda (do-macro)
|
||
(apply (lambda (do vars endtest . body)
|
||
(let ((do-loop (gensym)))
|
||
`(letrec ((,do-loop
|
||
(lambda ,(map (lambda (x)
|
||
(if (pair? x) (car x) x))
|
||
`,vars)
|
||
(if ,(car endtest)
|
||
(begin ,@(cdr endtest))
|
||
(begin
|
||
,@body
|
||
(,do-loop
|
||
,@(map (lambda (x)
|
||
(cond
|
||
((not (pair? x)) x)
|
||
((< (length x) 3) (car x))
|
||
(else (car (cdr (cdr x))))))
|
||
`,vars)))))))
|
||
(,do-loop
|
||
,@(map (lambda (x)
|
||
(if (and (pair? x) (cdr x))
|
||
(car (cdr x))
|
||
'()))
|
||
`,vars)))))
|
||
do-macro)))
|
||
|
||
;;;; generic-member
|
||
(define (generic-member cmp obj lst)
|
||
(cond
|
||
((null? lst) #f)
|
||
((cmp obj (car lst)) lst)
|
||
(else (generic-member cmp obj (cdr lst)))))
|
||
|
||
(define (memq obj lst)
|
||
(generic-member eq? obj lst))
|
||
(define (memv obj lst)
|
||
(generic-member eqv? obj lst))
|
||
(define (member obj lst)
|
||
(generic-member equal? obj lst))
|
||
|
||
;;;; generic-assoc
|
||
(define (generic-assoc cmp obj alst)
|
||
(cond
|
||
((null? alst) #f)
|
||
((cmp obj (caar alst)) (car alst))
|
||
(else (generic-assoc cmp obj (cdr alst)))))
|
||
|
||
(define (assq obj alst)
|
||
(generic-assoc eq? obj alst))
|
||
(define (assv obj alst)
|
||
(generic-assoc eqv? obj alst))
|
||
(define (assoc obj alst)
|
||
(generic-assoc equal? obj alst))
|
||
|
||
(define (acons x y z) (cons (cons x y) z))
|
||
|
||
;;;; Handy for imperative programs
|
||
;;;; Used as: (define-with-return (foo x y) .... (return z) ...)
|
||
(macro (define-with-return form)
|
||
`(define ,(cadr form)
|
||
(call/cc (lambda (return) ,@(cddr form)))))
|
||
|
||
;; Print the given history.
|
||
(define (vm-history-print history)
|
||
(let loop ((n 0) (skip 0) (frames history))
|
||
(cond
|
||
((null? frames)
|
||
#t)
|
||
((> skip 0)
|
||
(loop 0 (- skip 1) (cdr frames)))
|
||
(else
|
||
(let ((f (car frames)))
|
||
(display n)
|
||
(display ": ")
|
||
(let ((tag (get-tag f)))
|
||
(when (and (pair? tag) (string? (car tag)) (number? (cdr tag)))
|
||
(display (basename (car tag)))
|
||
(display ":")
|
||
(display (+ 1 (cdr tag)))
|
||
(display ": ")))
|
||
(write f))
|
||
(newline)
|
||
(loop (+ n 1) skip (cdr frames))))))
|
||
|
||
;;;; Simple exception handling
|
||
;
|
||
; Exceptions are caught as follows:
|
||
;
|
||
; (catch (do-something to-recover and-return meaningful-value)
|
||
; (if-something goes-wrong)
|
||
; (with-these calls))
|
||
;
|
||
; "Catch" establishes a scope spanning multiple call-frames until
|
||
; another "catch" is encountered. Within the recovery expression
|
||
; the thrown exception is bound to *error*. Errors can be rethrown
|
||
; using (rethrow *error*).
|
||
;
|
||
; Finalization can be expressed using "finally":
|
||
;
|
||
; (finally (finalize-something called-purely-for side-effects)
|
||
; (whether-or-not something goes-wrong)
|
||
; (with-these calls))
|
||
;
|
||
; The final expression is executed purely for its side-effects,
|
||
; both when the function exits successfully, and when an exception
|
||
; is thrown.
|
||
;
|
||
; Exceptions are thrown with:
|
||
;
|
||
; (throw "message")
|
||
;
|
||
; If used outside a (catch ...), reverts to (error "message")
|
||
|
||
(define *handlers* (list))
|
||
|
||
(define (push-handler proc)
|
||
(set! *handlers* (cons proc *handlers*)))
|
||
|
||
(define (pop-handler)
|
||
(let ((h (car *handlers*)))
|
||
(set! *handlers* (cdr *handlers*))
|
||
h))
|
||
|
||
(define (more-handlers?)
|
||
(pair? *handlers*))
|
||
|
||
;; This throws an exception.
|
||
(define (throw message . args)
|
||
(throw' message args (cdr (*vm-history*))))
|
||
|
||
;; This is used by the vm to throw exceptions.
|
||
(define (throw' message args history)
|
||
(cond
|
||
((and args (list? args) (= 2 (length args))
|
||
(equal? *interpreter-exit* (car args)))
|
||
(*run-atexit-handlers*)
|
||
(quit (cadr args)))
|
||
((more-handlers?)
|
||
((pop-handler) message args history))
|
||
(else
|
||
(display message)
|
||
(when (and args (not (null? args)))
|
||
(display ": ")
|
||
(if (and (pair? args) (string? (car args)))
|
||
(begin (display (car args))
|
||
(unless (null? (cdr args))
|
||
(newline)
|
||
(write (cdr args))))
|
||
(write args)))
|
||
(newline)
|
||
(vm-history-print history)
|
||
(quit 1))))
|
||
|
||
;; Convenience function to rethrow the error.
|
||
(define (rethrow e)
|
||
(apply throw' e))
|
||
|
||
(macro (catch form)
|
||
(let ((label (gensym)))
|
||
`(call/cc (lambda (**exit**)
|
||
(push-handler (lambda *error* (**exit** ,(cadr form))))
|
||
(let ((,label (begin ,@(cddr form))))
|
||
(pop-handler)
|
||
,label)))))
|
||
|
||
(define-macro (finally final-expression . expressions)
|
||
(let ((result (gensym)))
|
||
`(let ((,result (catch (begin ,final-expression (rethrow *error*))
|
||
,@expressions)))
|
||
,final-expression
|
||
,result)))
|
||
|
||
;; Make the vm use throw'.
|
||
(define *error-hook* throw')
|
||
|
||
|
||
|
||
;; High-level mechanism to terminate the process is to throw an error
|
||
;; of the form (*interpreter-exit* status). This gives automatic
|
||
;; resource management a chance to clean up.
|
||
(define *interpreter-exit* (gensym))
|
||
|
||
;; Terminate the process returning STATUS to the parent.
|
||
(define (exit status)
|
||
(throw "interpreter exit" *interpreter-exit* status))
|
||
|
||
;; A list of functions run at interpreter shutdown.
|
||
(define *atexit-handlers* (list))
|
||
|
||
;; Execute all these functions.
|
||
(define (*run-atexit-handlers*)
|
||
(unless (null? *atexit-handlers*)
|
||
(let ((proc (car *atexit-handlers*)))
|
||
;; Drop proc from the list so that it will not get
|
||
;; executed again even if it raises an exception.
|
||
(set! *atexit-handlers* (cdr *atexit-handlers*))
|
||
(proc)
|
||
(*run-atexit-handlers*))))
|
||
|
||
;; Register a function to be run at interpreter shutdown.
|
||
(define (atexit proc)
|
||
(set! *atexit-handlers* (cons proc *atexit-handlers*)))
|
||
|
||
|
||
|
||
;;;;; Definition of MAKE-ENVIRONMENT, to be used with two-argument EVAL
|
||
|
||
(macro (make-environment form)
|
||
`(apply (lambda ()
|
||
,@(cdr form)
|
||
(current-environment))))
|
||
|
||
(define-macro (eval-polymorphic x . envl)
|
||
(display envl)
|
||
(let* ((env (if (null? envl) (current-environment) (eval (car envl))))
|
||
(xval (eval x env)))
|
||
(if (closure? xval)
|
||
(make-closure (get-closure-code xval) env)
|
||
xval)))
|
||
|
||
; Redefine this if you install another package infrastructure
|
||
; Also redefine 'package'
|
||
(define *colon-hook* eval)
|
||
|
||
(macro (package form)
|
||
`(apply (lambda ()
|
||
,@(cdr form)
|
||
(current-environment))))
|
||
|
||
(define-macro (export name . expressions)
|
||
`(define ,name
|
||
(begin
|
||
,@expressions)))
|
||
|
||
;;;;; I/O
|
||
|
||
(define (input-output-port? p)
|
||
(and (input-port? p) (output-port? p)))
|
||
|
||
(define (close-port p)
|
||
(cond
|
||
((input-output-port? p) (close-input-port p) (close-output-port p))
|
||
((input-port? p) (close-input-port p))
|
||
((output-port? p) (close-output-port p))
|
||
(else (throw "Not a port" p))))
|
||
|
||
(define (call-with-input-file s p)
|
||
(let ((inport (open-input-file s)))
|
||
(if (eq? inport #f)
|
||
#f
|
||
(let ((res (p inport)))
|
||
(close-input-port inport)
|
||
res))))
|
||
|
||
(define (call-with-output-file s p)
|
||
(let ((outport (open-output-file s)))
|
||
(if (eq? outport #f)
|
||
#f
|
||
(let ((res (p outport)))
|
||
(close-output-port outport)
|
||
res))))
|
||
|
||
(define (with-input-from-file s p)
|
||
(let ((inport (open-input-file s)))
|
||
(if (eq? inport #f)
|
||
#f
|
||
(let ((prev-inport (current-input-port)))
|
||
(set-input-port inport)
|
||
(let ((res (p)))
|
||
(close-input-port inport)
|
||
(set-input-port prev-inport)
|
||
res)))))
|
||
|
||
(define (with-output-to-file s p)
|
||
(let ((outport (open-output-file s)))
|
||
(if (eq? outport #f)
|
||
#f
|
||
(let ((prev-outport (current-output-port)))
|
||
(set-output-port outport)
|
||
(let ((res (p)))
|
||
(close-output-port outport)
|
||
(set-output-port prev-outport)
|
||
res)))))
|
||
|
||
(define (with-input-output-from-to-files si so p)
|
||
(let ((inport (open-input-file si))
|
||
(outport (open-input-file so)))
|
||
(if (not (and inport outport))
|
||
(begin
|
||
(close-input-port inport)
|
||
(close-output-port outport)
|
||
#f)
|
||
(let ((prev-inport (current-input-port))
|
||
(prev-outport (current-output-port)))
|
||
(set-input-port inport)
|
||
(set-output-port outport)
|
||
(let ((res (p)))
|
||
(close-input-port inport)
|
||
(close-output-port outport)
|
||
(set-input-port prev-inport)
|
||
(set-output-port prev-outport)
|
||
res)))))
|
||
|
||
; Random number generator (maximum cycle)
|
||
(define *seed* 1)
|
||
(define (random-next)
|
||
(let* ((a 16807) (m 2147483647) (q (quotient m a)) (r (modulo m a)))
|
||
(set! *seed*
|
||
(- (* a (- *seed*
|
||
(* (quotient *seed* q) q)))
|
||
(* (quotient *seed* q) r)))
|
||
(if (< *seed* 0) (set! *seed* (+ *seed* m)))
|
||
*seed*))
|
||
;; SRFI-0
|
||
;; COND-EXPAND
|
||
;; Implemented as a macro
|
||
(define *features* '(srfi-0 tinyscheme))
|
||
|
||
(define-macro (cond-expand . cond-action-list)
|
||
(cond-expand-runtime cond-action-list))
|
||
|
||
(define (cond-expand-runtime cond-action-list)
|
||
(if (null? cond-action-list)
|
||
#t
|
||
(if (cond-eval (caar cond-action-list))
|
||
`(begin ,@(cdar cond-action-list))
|
||
(cond-expand-runtime (cdr cond-action-list)))))
|
||
|
||
(define (cond-eval-and cond-list)
|
||
(foldr (lambda (x y) (and (cond-eval x) (cond-eval y))) #t cond-list))
|
||
|
||
(define (cond-eval-or cond-list)
|
||
(foldr (lambda (x y) (or (cond-eval x) (cond-eval y))) #f cond-list))
|
||
|
||
(define (cond-eval condition)
|
||
(cond
|
||
((symbol? condition)
|
||
(if (member condition *features*) #t #f))
|
||
((eq? condition #t) #t)
|
||
((eq? condition #f) #f)
|
||
(else (case (car condition)
|
||
((and) (cond-eval-and (cdr condition)))
|
||
((or) (cond-eval-or (cdr condition)))
|
||
((not) (if (not (null? (cddr condition)))
|
||
(error "cond-expand : 'not' takes 1 argument")
|
||
(not (cond-eval (cadr condition)))))
|
||
(else (error "cond-expand : unknown operator" (car condition)))))))
|
||
|
||
(gc-verbose #f)
|