678 lines
24 KiB
Scheme
678 lines
24 KiB
Scheme
;;; Regexp support for Scheme
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;;; Olin Shivers, January 1997, May 1998.
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;;; Todo:
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;;; - Better unparsers for (word ...) and (word+ ...).
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;;; - Unparse char-sets into set-diff SREs -- find a char set that's a
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;;; tight bound, then get the difference. This would really pretty up
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;;; things like (- alpha "aeiou")
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;;; Exports:
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;;; (sre->regexp sre) SRE->ADT parser
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;;; (regexp->sre re) ADT->SRE unparser
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;;;
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;;; Procedures that parse sexp regexps and translate ADTs for low-level macros:
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;;; (parse-sre sre rename compare)
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;;; (parse-sres sres rename compare)
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;;; (regexp->scheme re rename)
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;;;
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;;; (char-set->in-pair cset) Char-set unparsing utility
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;;; Character-set dependencies:
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;;; The only stuff in here dependent on the implementation's character type
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;;; is the char-set parsing and unparsing, which deal with ranges of
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;;; characters. We assume an 8-bit ASCII superset.
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;;; Imports:
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;;; ? for COND, and SWITCHQ conditional form.
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;;; every
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;;; This code is much hairier than it would otherwise be because of the
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;;; the presence of ,<exp> forms, which put a static/dynamic duality over
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;;; a lot of the processing -- we have to be prepared to handle either
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;;; re's or Scheme epressions that produce re's; char-sets or Scheme
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;;; expressions that produce char-sets. It's a pain.
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;;;
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;;; See comments in re.scm ADT code about building regexp trees that have
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;;; code in the record fields instead of values.
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;;;
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;;; The macro expander works by parsing the regexp form into an re record,
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;;; and simplifying it. If the record is completely static, it is then
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;;; translated, at macro-expand time, into a Posix regex string. If the
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;;; regexp needs runtime values -- e.g, the computed from and to fields in
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;;; (** "ha, " (- min 1) (+ max 1))
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;;; -- the expander instead produces Scheme ADT constructors to build
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;;; the regexp at run-time.
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;;; Parser
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;; Is a parsed regexp completely determined statically, or does it
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;;; have dynamic components (e.g., a ,@<pattern> or a computed char-set)
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;;; in the form of embedded code in some of the regexp's fields?
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(define (static-regexp? re)
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(? ((re-seq? re) (every static-regexp? (re-seq:elts re)))
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((re-choice? re) (every static-regexp? (re-choice:elts re)))
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((re-char-set? re) (char-set? (re-char-set:cset re))) ; Might be code.
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((re-repeat? re) ; FROM & TO fields might be code.
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(let ((to (re-repeat:to re)))
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(and (integer? (re-repeat:from re))
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(or (not to) (integer? to))
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(static-regexp? (re-repeat:body re)))))
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((re-dsm? re) (static-regexp? (re-dsm:body re)))
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((re-submatch? re) (static-regexp? (re-submatch:body re)))
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(else (or (re-bos? re) (re-eos? re) ; Otw, if it's not
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(re-bol? re) (re-eol? re) ; one of these,
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(re-bow? re) (re-eow? re) ; then it's Scheme code.
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(re-string? re)))))
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;;; Two useful standard char sets
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(define nonl-chars (char-set-complement (char-set #\newline)))
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(define word-chars (char-set-union (char-set #\_) char-set:letter+digit))
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;;; Little utility that should be moved to scsh's utilities.scm
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(define (partition pred lis)
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(let recur ((in '()) (out '()) (lis lis))
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(if (pair? lis)
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(let ((head (car lis))
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(tail (cdr lis)))
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(if (pred head)
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(recur (cons head in) out tail)
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(recur in (cons head out) tail)))
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(values in out))))
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(define (sre->regexp sre)
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(parse-sre sre (lambda (x) x) equal?))
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;;; Parse a sexp regexp into a regexp value, which may be "dynamic" --
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;;; i.e., some slots may be filled with the Scheme code that will produce
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;;; their true vaues.
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;;;
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;;; R & C are rename and compare functions for low-level macro expanders.
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;;; These two guys are little front-ends for the main routine.
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(define (parse-sre sre r c) (parse-sre/context sre #t #f r c))
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(define (parse-sres sres r c)
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(re-seq (map (lambda (sre) (parse-sre sre r c)) sres)))
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;;; (parse-sre/context sre case-sensitive? cset? r c)
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;; This is the main entry point. Parse SRE, given the lexical case-sensitivity
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;;; flag CASE-SENSITIVE?. If CSET? is true, SRE *must* be parseable as a
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;;; char-class SRE, and this function returns a character set, *not* a
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;;; regexp value. If CSET? is false, SRE can be any SRE, and this function
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;;; returns a regexp value. R and C are low-level macro rename and compare
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;;; functions.
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(define (parse-sre/context sre case-sensitive? cset? r c)
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(let ((%bos (r 'bos)) (%eos (r 'eos))
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(%bol (r 'bol)) (%eol (r 'eol))
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(%bow (r 'bow)) (%eow (r 'eow))
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(%word (r 'word))
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(%flush-submatches (r 'flush-submatches))
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(%coerce-dynamic-charset (r 'coerce-dynamic-charset))
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(%coerce-dynamic-regexp (r 'coerce-dynamic-regexp)))
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(let recur ((sre sre)
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(case-sensitive? case-sensitive?)
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(cset? cset?))
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;; Parse the sequence of regexp expressions SEQ with a lexical
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;; case-sensitivity context of CS?.
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(define (parse-seq/context seq cs?)
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(if cset?
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(if (= 1 (length seq))
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(recur (car sre) cs? #t)
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(error "Non-singleton sequence not allowed in char-class context."
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seq))
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(re-seq (map (lambda (sre) (recur sre cs? cset?))
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seq))))
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(define (parse-seq seq) (parse-seq/context seq case-sensitive?))
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(define (parse-char-class sre) (recur sre case-sensitive? #t))
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(define (non-cset) ; Blow up if cset? is true.
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(if cset? (error "Illegal SRE in char-class context." sre)))
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(? ((char? sre) (parse-char-re sre case-sensitive? cset?))
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((string? sre) (parse-string-re sre case-sensitive? cset?))
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((c sre %bos) (non-cset) re-bos)
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((c sre %eos) (non-cset) re-eos)
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((c sre %bol) (non-cset) re-bol)
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((c sre %eol) (non-cset) re-eol)
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((c sre %bow) (non-cset) re-bow)
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((c sre %eow) (non-cset) re-eow)
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((c sre %word) (non-cset) re-word)
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((pair? sre)
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(let ((hygn-eq? (lambda (the-sym) (c (car sre) (r the-sym)))))
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(cond
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((hygn-eq? '*) (non-cset) (re-repeat 0 #f (parse-seq (cdr sre))))
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((hygn-eq? '+) (non-cset) (re-repeat 1 #f (parse-seq (cdr sre))))
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((hygn-eq? '?) (non-cset) (re-repeat 0 1 (parse-seq (cdr sre))))
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((hygn-eq? '=) (non-cset) (let ((n (cadr sre)))
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(re-repeat n n (parse-seq (cddr sre)))))
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((hygn-eq? '>=) (non-cset) (re-repeat (cadr sre) #f (parse-seq (cddr sre))))
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((hygn-eq? '**) (non-cset) (re-repeat (cadr sre) (caddr sre)
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(parse-seq (cdddr sre))))
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;; Choice is special wrt cset? because it's "polymorphic".
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;; Note that RE-CHOICE guarantees to construct a char-set
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;; or single-char string regexp if all of its args are char
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;; classes.
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((or (hygn-eq? '|)
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(hygn-eq? 'or))
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(let ((elts (map (lambda (sre)
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(recur sre case-sensitive? cset?))
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(cdr sre))))
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(if cset?
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(assoc-cset-op char-set-union 'char-set-union elts r)
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(re-choice elts))))
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((or (hygn-eq? ':)
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(hygn-eq? 'seq))
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(non-cset) (parse-seq (cdr sre)))
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((hygn-eq? 'word) (non-cset) (parse-seq `(,%bow ,@(cdr sre) ,%eow)))
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((hygn-eq? 'word+)
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(recur `(,(r 'word) (,(r '+) (,(r '&) (,(r '|) ,(r 'alphanum) "_")
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(,(r '|) . ,(cdr sre)))))
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case-sensitive?
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cset?))
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((hygn-eq? 'submatch) (non-cset) (re-submatch (parse-seq (cdr sre))))
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((hygn-eq? 'dsm) (non-cset) (re-dsm (parse-seq (cdddr sre))
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(cadr sre)
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(caddr sre)))
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;; We could be more aggressive and push the uncase op down into
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;; partially-static regexps, but enough is enough.
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((hygn-eq? 'uncase)
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(let ((re-or-cset (parse-seq (cdr sre)))) ; Depending on CSET?.
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(if cset?
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(if (re-char-set? re-or-cset) ; A char set or code
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(uncase-char-set re-or-cset) ; producing a char set.
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`(,(r 'uncase) ,re-or-cset))
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(if (static-regexp? re-or-cset) ; A regexp or code
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(uncase re-or-cset) ; producing a regexp.
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`(,(r 'uncase)
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,(regexp->scheme (simplify-regexp re-or-cset) r))))))
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;; These just change the lexical case-sensitivity context.
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((hygn-eq? 'w/nocase) (parse-seq/context (cdr sre) #f))
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((hygn-eq? 'w/case) (parse-seq/context (cdr sre) #t))
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;; ,<exp> and ,@<exp>
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((hygn-eq? 'unquote)
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(let ((exp (cadr sre)))
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(if cset?
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`(,%coerce-dynamic-charset ,exp)
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`(,%flush-submatches (,%coerce-dynamic-regexp ,exp)))))
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((hygn-eq? 'unquote-splicing)
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(let ((exp (cadr sre)))
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(if cset?
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`(,%coerce-dynamic-charset ,exp)
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`(,%coerce-dynamic-regexp ,exp))))
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((hygn-eq? '~) (let* ((cs (assoc-cset-op char-set-union 'char-set-union
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(map parse-char-class (cdr sre))
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r))
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(cs (if (char-set? cs)
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(char-set-complement cs)
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`(,(r 'char-set-complement) ,cs))))
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(if cset? cs (make-re-char-set cs))))
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((hygn-eq? '&) (let ((cs (assoc-cset-op char-set-intersection 'char-set-intersection
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(map parse-char-class (cdr sre))
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r)))
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(if cset? cs (make-re-char-set cs))))
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((hygn-eq? '-) (if (pair? (cdr sre))
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(let* ((cs1 (parse-char-class (cadr sre)))
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(cs2 (assoc-cset-op char-set-union 'char-set-union
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(map parse-char-class (cddr sre))
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r))
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(cs (if (and (char-set? cs1) (char-set? cs2))
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(char-set-difference cs1 cs2)
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`(,(r 'char-set-difference)
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,(if (char-set? cs1)
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(char-set->scheme cs1 r)
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cs1)
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. ,(if (char-set? cs2)
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(list (char-set->scheme cs2 r))
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(cdr cs2))))))
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(if cset? cs (make-re-char-set cs)))
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(error "SRE set-difference operator (- ...) requires at least one argument")))
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((hygn-eq? '/) (let ((cset (range-class->char-set (cdr sre) case-sensitive?)))
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(if cset? cset (make-re-char-set cset))))
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((hygn-eq? 'posix-string)
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(if (and (= 1 (length (cdr sre)))
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(string? (cadr sre)))
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(posix-string->regexp (cadr sre))
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(error "Illegal (posix-string ...) SRE body." sre)))
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(else (if (every string? sre) ; A set spec -- ("wxyz").
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(let* ((cs (apply char-set-union
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(map string->char-set sre)))
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(cs (if case-sensitive? cs (uncase-char-set cs))))
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(if cset? cs (make-re-char-set cs)))
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(error "Illegal SRE" sre))))))
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;; It must be a char-class name (ANY, ALPHABETIC, etc.)
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(else
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(letrec ((hygn-memq? (lambda (sym-list)
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(if (null? sym-list)
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#f
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(or (c sre (r (car sym-list)))
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(hygn-memq? (cdr sym-list)))))))
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(let ((cs (cond
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((hygn-memq? '(any)) char-set:full)
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((hygn-memq? '(nonl)) nonl-chars)
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((hygn-memq? '(lower-case lower)) char-set:lower-case)
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((hygn-memq? '(upper-case upper)) char-set:upper-case)
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((hygn-memq? '(alphabetic alpha)) char-set:letter)
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((hygn-memq? '(numeric digit num)) char-set:digit)
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((hygn-memq? '(alphanumeric alnum alphanum)) char-set:letter+digit)
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((hygn-memq? '(punctuation punct)) char-set:punctuation)
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((hygn-memq? '(graphic graph)) char-set:graphic)
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((hygn-memq? '(blank)) char-set:blank)
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((hygn-memq? '(whitespace space white)) char-set:whitespace)
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((hygn-memq? '(printing print)) char-set:printing)
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((hygn-memq? '(control cntrl)) char-set:iso-control)
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((hygn-memq? '(hex-digit xdigit hex)) char-set:hex-digit)
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((hygn-memq? '(ascii)) char-set:ascii)
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(else (error "Illegal regular expression" sre)))))
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(if cset? cs (make-re-char-set cs)))))))))
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;;; In a CSET? true context, S must be a 1-char string; convert to a char set
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;;; according to CASE-SENSITIVE? setting.
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;;; In a CSET? false context, convert S to a string re (CASE-SENSITIVE? true),
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;;; or a sequence of char-sets (CASE-SENSITIVE? false).
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(define (parse-string-re s case-sensitive? cset?)
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(if (= 1 (string-length s))
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(parse-char-re (string-ref s 0) case-sensitive? cset?)
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(if cset?
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(error "Non-singleton string not allowed in char-class context." s)
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((if case-sensitive? make-re-string uncase-string) s))))
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(define (parse-char-re c case-sensitive? cset?)
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(if case-sensitive?
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(if cset? (char-set c) (make-re-string (string c)))
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(let ((cset (char-set (char-upcase c) (char-downcase c))))
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(if cset? cset (make-re-char-set cset)))))
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;;; "Apply" the associative char-set function OP to the char-sets ELTS.
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;;; If any of the ELTS is Scheme code instead of a real char set, then
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;;; we instead produce Scheme code for the op, using OP-NAME as the name
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;;; of the function, and R for the macro renamer function.
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(define (assoc-cset-op op op-name elts r)
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(receive (csets code-chunks) (partition char-set? elts)
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(if (pair? code-chunks)
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(? ((pair? csets)
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`(,(r op-name) ,(char-set->scheme (apply op csets) r)
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. ,code-chunks))
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((pair? (cdr code-chunks)) `(,(r op-name) . ,code-chunks))
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(else (car code-chunks))) ; Just one.
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(apply op csets))))
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;;; Parse a (/ <range-spec> ...) char-class into a character set in
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;;; case-sensitivity context CS?.
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;;; Each <range-spec> can be a character or a string of characters.
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(define (range-class->char-set range-specs cs?)
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(let* ((specs (apply string-append
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(map (lambda (spec) (if (char? spec) (string spec) spec))
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range-specs)))
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(len (string-length specs))
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(cset (char-set-copy char-set:empty)))
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(if (odd? len)
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(error "Unmatched range specifier" range-specs)
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(let lp ((i (- len 1)) (cset cset))
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(if (< i 0)
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(if cs? cset (uncase-char-set cset)) ; Case fold if necessary.
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(lp (- i 2)
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(ucs-range->char-set! (char->ascii (string-ref specs (- i 1)))
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(+ 1 (char->ascii (string-ref specs i)))
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#f cset)))))))
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;;; (regexp->scheme re r)
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;; Translate a regexp value RE into raw Scheme code that will create it, with
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;;; calls to the regexp ADT constructor functions. R is a renaming function
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;;; provided by low-level macro expanders.
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(define (regexp->scheme re r)
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(let ((%re-bos (r 're-bos)) (%re-eos (r 're-eos))
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(%re-bol (r 're-bol)) (%re-eol (r 're-eol))
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(%re-bow (r 're-bow)) (%re-eow (r 're-eow))
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(%list (r 'list)))
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(let recur ((re re))
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;; If (fetch-posix re) = #f, produce (OP . ARGS);
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;; Otherwise, produce (OP/POSIX ,@ARGS '<posix-translation>).
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(define (doit op op/posix args fetch-posix)
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(? ((fetch-posix re) =>
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(lambda (psx) `(,(r op/posix) ,@args
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',(cre:string psx) ',(cre:tvec psx))))
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(else `(,(r op) . ,args))))
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(? ((re-string? re) (if (re-trivial? re) (r 're-trivial) ; Special hack
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(doit 'make-re-string 'make-re-string/posix
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`(,(re-string:chars re))
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re-string:posix)))
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((re-seq? re) (doit '%make-re-seq '%make-re-seq/posix
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`((,%list . ,(map recur (re-seq:elts re)))
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,(re-seq:tsm re))
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re-seq:posix))
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((re-choice? re) (doit '%make-re-choice '%make-re-choice/posix
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`((,%list . ,(map recur (re-choice:elts re)))
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,(re-choice:tsm re))
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re-choice:posix))
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((re-char-set? re) (if (re-any? re) (r 're-any) ; Special hack for ANY.
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(doit 'make-re-char-set 'make-re-char-set/posix
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`(,(char-set->scheme (re-char-set:cset re) r))
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re-char-set:posix)))
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|
|
|
((re-repeat? re) (doit '%make-re-repeat '%make-re-repeat/posix
|
|
`(,(re-repeat:from re)
|
|
,(re-repeat:to re)
|
|
,(recur (re-repeat:body re))
|
|
,(re-repeat:tsm re))
|
|
re-repeat:posix))
|
|
|
|
((re-dsm? re) (doit '%make-re-dsm '%make-re-dsm/posix
|
|
`(,(recur (re-dsm:body re))
|
|
,(re-dsm:pre-dsm re)
|
|
,(re-dsm:tsm re))
|
|
re-dsm:posix))
|
|
|
|
((re-submatch? re) (doit '%make-re-submatch '%make-re-submatch/posix
|
|
`(,(recur (re-submatch:body re))
|
|
,(re-submatch:pre-dsm re)
|
|
,(re-submatch:tsm re))
|
|
re-submatch:posix))
|
|
|
|
((re-bos? re) %re-bos)
|
|
((re-eos? re) %re-eos)
|
|
((re-bol? re) %re-bol)
|
|
((re-eol? re) %re-eol)
|
|
((re-bow? re) %re-bow)
|
|
((re-eow? re) %re-eow)
|
|
|
|
(else re)))))
|
|
|
|
|
|
|
|
;;; Classify a character set.
|
|
;;; We pass in a char set CS and 15 parameters, one for each of the
|
|
;;; standard char sets. If we can classify CS as any of these char
|
|
;;; sets, we return the corresponding parameter's value, otw #f.
|
|
;;;
|
|
;;; This is gratuitously optimised by probing cset with a couple of
|
|
;;; witness chars (a,A,1,space), and doing an initial filter based
|
|
;;; on these witnesses.
|
|
|
|
(define (try-classify-char-set cs
|
|
full nonl lower upper alpha num alphanum
|
|
punct graph white print ctl hex blank ascii)
|
|
(let ((a (char-set-contains? cs #\a))
|
|
(biga (char-set-contains? cs #\A))
|
|
(one (char-set-contains? cs #\1))
|
|
(space (char-set-contains? cs #\space)))
|
|
|
|
(if a
|
|
(if biga
|
|
(if space
|
|
(and one (switch char-set= cs
|
|
((char-set:full) full)
|
|
((nonl-chars) nonl)
|
|
((char-set:printing) print)
|
|
((char-set:ascii) ascii)
|
|
(else #f)))
|
|
(if one
|
|
(switch char-set= cs
|
|
((char-set:letter+digit) alphanum)
|
|
((char-set:graphic) graph)
|
|
((char-set:hex-digit) hex)
|
|
(else #f))
|
|
(and (char-set= cs char-set:letter) alpha)))
|
|
(and (char-set= cs char-set:lower-case) lower)) ; a, not A
|
|
|
|
(if biga
|
|
(and (not space) (char-set= cs char-set:upper-case) upper)
|
|
(if one
|
|
(and (not space) (char-set= cs char-set:digit) num)
|
|
(if space
|
|
(switch char-set= cs
|
|
((char-set:whitespace) white)
|
|
((char-set:blank) blank)
|
|
(else #f))
|
|
(switch char-set= cs
|
|
((char-set:punctuation) punct)
|
|
((char-set:iso-control) ctl)
|
|
(else #f))))))))
|
|
|
|
|
|
(define (char-set->scheme cs r)
|
|
(let ((try (lambda (cs)
|
|
(try-classify-char-set cs
|
|
'char-set:full 'nonl-chars
|
|
'char-set:lower-case 'char-set:upper-case
|
|
'char-set:letter 'char-set:digit
|
|
'char-set:letter+digit 'char-set:punctuation
|
|
'char-set:graphic 'char-set:whitespace
|
|
'char-set:printing 'char-set:iso-control
|
|
'char-set:hex-digit 'char-set:blank
|
|
'char-set:ascii))))
|
|
(? ((not (char-set? cs)) cs) ; Dynamic -- *already* Scheme code.
|
|
((char-set-empty? cs) (r 'char-set:empty))
|
|
((try cs) => r)
|
|
((try (char-set-complement cs)) =>
|
|
(lambda (name) `(,(r 'char-set-complement) ,name)))
|
|
|
|
(else
|
|
(receive (loose+ ranges+) (char-set->in-pair cs)
|
|
(receive (loose- ranges-) (char-set->in-pair (char-set-complement cs))
|
|
(let ((makeit (r 'spec->char-set)))
|
|
(if (< (+ (length loose-) (* 12 (length ranges-)))
|
|
(+ (length loose+) (* 12 (length ranges+))))
|
|
`(,makeit #f ,(list->string loose-) ',ranges-)
|
|
`(,makeit #t ,(list->string loose+) ',ranges+)))))))))
|
|
|
|
|
|
|
|
;;; This code needs work.
|
|
|
|
(define (char-set->sre cs r)
|
|
(if (char-set? cs)
|
|
(let ((try (lambda (cs)
|
|
(try-classify-char-set cs
|
|
'any 'nonl
|
|
'lower-case 'upper-case
|
|
'alphabetic 'numeric
|
|
'alphanumeric 'punctuation
|
|
'graphic 'whitespace
|
|
'printing 'control
|
|
'hex-digit 'blank
|
|
'ascii)))
|
|
(nchars (char-set-size cs)))
|
|
(? ((zero? nchars) `(,(r '|)))
|
|
((= 1 nchars) (apply string (char-set->list cs)))
|
|
((try cs) => r)
|
|
((try (char-set-complement cs)) =>
|
|
(lambda (name) `(,(r '~) ,name)))
|
|
(else (receive (cs rp comp?) (char-set->in-sexp-spec cs)
|
|
(let ((args (append (? ((string=? cs "") '())
|
|
((= 1 (string-length cs)) `(,cs))
|
|
(else `((,cs))))
|
|
(if (string=? rp "") '()
|
|
(list `(,(r '/) ,rp))))))
|
|
(if (and (= 1 (length args)) (not comp?))
|
|
(car args)
|
|
`(,(r (if comp? '~ '|)) . ,args)))))))
|
|
|
|
`(,(r 'unquote) ,cs))) ; dynamic -- ,<cset-exp>
|
|
|
|
|
|
;;; Unparse an re into a *list* of SREs (representing a sequence).
|
|
;;; This is for rendering the bodies of DSM, SUBMATCH, **, *, =, >=, and &'s,
|
|
;;; that is, forms whose body is an implicit sequence.
|
|
|
|
(define (regexp->sres/renamer re r)
|
|
(if (re-seq? re)
|
|
(let ((elts (re-seq:elts re)))
|
|
(if (pair? elts)
|
|
(map (lambda (re) (regexp->sre/renamer re r)) elts)
|
|
(let ((tsm (re-seq:tsm re))
|
|
(%dsm (r 'dsm)))
|
|
(if (zero? tsm) '() `((,%dsm ,tsm 0)))))) ; Empty sequence
|
|
(list (regexp->sre/renamer re r)))) ; Not a seq
|
|
|
|
|
|
(define (regexp->sre/renamer re r)
|
|
(let recur ((re re))
|
|
(? ((re-string? re) (re-string:chars re))
|
|
|
|
((re-seq? re) `(,(r ':) . ,(regexp->sres/renamer re r)))
|
|
|
|
((re-choice? re)
|
|
(let ((elts (re-choice:elts re))
|
|
(%| (r '|)))
|
|
(if (pair? elts)
|
|
`(,%| . ,(map recur elts))
|
|
(let ((tsm (re-choice:tsm re)))
|
|
(if (zero? tsm) `(,%|) `(,(r 'dsm) ,tsm 0 (,%|)))))))
|
|
|
|
((re-char-set? re) (char-set->sre (re-char-set:cset re) r))
|
|
|
|
((re-repeat? re)
|
|
(let ((from (re-repeat:from re))
|
|
(to (re-repeat:to re))
|
|
(bodies (regexp->sres/renamer (re-repeat:body re) r)))
|
|
(? ((and (eqv? from 0) (not to)) `(,(r '*) . ,bodies))
|
|
((and (eqv? from 0) (eqv? to 1)) `(,(r '?) . ,bodies))
|
|
((and (eqv? from 1) (not to)) `(,(r '+) . ,bodies))
|
|
((eqv? from to) `(,(r '=) ,to . bodies))
|
|
(to `(,(r '**) ,from ,to . ,bodies))
|
|
(else `(,(r '>=) ,from . ,bodies)))))
|
|
|
|
((re-dsm? re)
|
|
`(,(r 'dsm) ,(re-dsm:pre-dsm re) ,(re-dsm:post-dsm re)
|
|
. ,(regexp->sres/renamer (re-dsm:body re) r)))
|
|
|
|
((re-submatch? re)
|
|
`(,(r 'submatch) . ,(regexp->sres/renamer (re-submatch:body re) r)))
|
|
|
|
((re-bos? re) (r 'bos))
|
|
((re-eos? re) (r 'eos))
|
|
((re-bol? re) (r 'bol))
|
|
((re-eol? re) (r 'eol))
|
|
((re-bow? re) (r 'bow))
|
|
((re-eow? re) (r 'eow))
|
|
|
|
(else re)))) ; Presumably it's code.
|
|
|
|
(define (regexp->sre re) (regexp->sre/renamer re (lambda (x) x)))
|
|
|
|
;;; Character class unparsing
|
|
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
|
;;; This is the code that takes char-sets and converts them into forms suitable
|
|
;;; for char-class SRE's or [...] Posix strings.
|
|
|
|
;;; Map a char-set to an (| ("...") (/"...")) or (~ ("...") (/"...")) SRE.
|
|
;;; We try it both ways, and return whichever is shortest.
|
|
;;; We return three values:
|
|
;;; - a string of chars that are members in the set;
|
|
;;; - a string of chars that, taken in pairs specifying ranges,
|
|
;;; give the rest of the members of the set.
|
|
;;; - A boolean COMP?, which says whether the set should be complemented
|
|
;;; (~ ...) or taken as-is (| ...).
|
|
;;;
|
|
;;; E.g., ["!?.", "AZaz09", #t]
|
|
|
|
(define (char-set->in-sexp-spec cset)
|
|
(let ((->sexp-pair (lambda (cset)
|
|
(receive (loose ranges) (char-set->in-pair cset)
|
|
(values (apply string loose)
|
|
(apply string
|
|
(fold-right (lambda (r lis)
|
|
`(,(car r) ,(cdr r) . ,lis))
|
|
'() ranges)))))))
|
|
(receive (cs+ rp+) (->sexp-pair cset)
|
|
(receive (cs- rp-) (->sexp-pair (char-set-complement cset))
|
|
(if (< (+ (string-length cs-) (string-length rp-))
|
|
(+ (string-length cs+) (string-length rp+)))
|
|
(values cs- rp- #t)
|
|
(values cs+ rp+ #f))))))
|
|
|
|
;;; Return 2 values characterizing the char set in a run-length encoding:
|
|
;;; - LOOSE List of singleton chars -- elts of the set.
|
|
;;; - RANGES List of (from . to) char ranges.
|
|
;;;
|
|
;;; E.g., [(#\! #\? #\.)
|
|
;;; ((#\A . #\Z) (#\a . #\z) (#\0 . #\9))]
|
|
|
|
(define (char-set->in-pair cset)
|
|
(let ((add-range (lambda (from to loose ranges)
|
|
(if from (case (- to from)
|
|
((0) (values (cons (ascii->char from) loose)
|
|
ranges))
|
|
((1) (values `(,(ascii->char from)
|
|
,(ascii->char to)
|
|
. ,loose)
|
|
ranges))
|
|
((2) (values `(,(ascii->char from)
|
|
,(ascii->char (+ from 1))
|
|
,(ascii->char to)
|
|
. ,loose)
|
|
ranges))
|
|
(else (values loose
|
|
`((,(ascii->char from) .
|
|
,(ascii->char to))
|
|
. ,ranges))))
|
|
(values loose ranges)))))
|
|
|
|
(let lp ((i 127) (from #f) (to #f) (loose '()) (ranges '()))
|
|
(if (< i 0)
|
|
(add-range from to loose ranges)
|
|
|
|
(let ((i-1 (- i 1)))
|
|
(if (char-set-contains? cset (ascii->char i))
|
|
(if from
|
|
(lp i-1 i to loose ranges) ; Continue the run.
|
|
(lp i-1 i i loose ranges)) ; Start a new run.
|
|
|
|
;; If there's a run going, finish it off.
|
|
(receive (loose ranges) (add-range from to loose ranges)
|
|
(lp i-1 #f #f loose ranges))))))))
|