916 lines
32 KiB
Scheme
916 lines
32 KiB
Scheme
;;; SRFI-14 character-sets library -*- Scheme -*-
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;;;
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;;; - Ported from MIT Scheme runtime by Brian D. Carlstrom.
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;;; - Massively rehacked & extended by Olin Shivers 6/98.
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;;; - Massively redesigned and rehacked 5/2000 during SRFI process.
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;;; At this point, the code bears the following relationship to the
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;;; MIT Scheme code: "This is my grandfather's axe. My father replaced
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;;; the head, and I have replaced the handle." Nonetheless, we preserve
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;;; the MIT Scheme copyright:
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;;; Copyright (c) 1988-1995 Massachusetts Institute of Technology
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;;; The MIT Scheme license is a "free software" license. See the end of
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;;; this file for the tedious details.
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;;;
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;;;
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;;; On 16 Dec 2003, Olin added the following comment in a private email
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;;; to Mike Sperber, Jonathan Rees and Martin Gasbichler:
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;;;
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;;; This code has nothing in common w/the MIT code. Just check it out.
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;;; The only connection is (1) some of the API design and (2) the basic
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;;; data-structure (a 256-elt string of \000 & non-\000 chars), which is
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;;; obvious art. I was being overly generous when I included the MIT copyright.
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;;; The system was completely rewritten for the 2000 SRFI reference version;
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;;; I should have removed the MIT notices then. In particular, as a casual
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;;; examination will show, the implementation of the common API is *quite*
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;;; different -- I don't even mean at the in-the-small level, but at the
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;;; medium-level architectural/structural details.
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;;; Exports:
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;;; char-set? char-set= char-set<=
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;;; char-set-hash
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;;; char-set-cursor char-set-ref char-set-cursor-next end-of-char-set?
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;;; char-set-fold char-set-unfold char-set-unfold!
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;;; char-set-for-each char-set-map
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;;; char-set-copy char-set
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;;;
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;;; list->char-set string->char-set
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;;; list->char-set! string->char-set!
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;;;
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;;; filterchar-set ucs-range->char-set ->char-set
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;;; filterchar-set! ucs-range->char-set!
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;;;
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;;; char-set->list char-set->string
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;;;
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;;; char-set-size char-set-count char-set-contains?
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;;; char-set-every char-set-any
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;;;
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;;; char-set-adjoin char-set-delete
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;;; char-set-adjoin! char-set-delete!
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;;;
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;;; char-set-complement char-set-union char-set-intersection
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;;; char-set-complement! char-set-union! char-set-intersection!
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;;;
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;;; char-set-difference char-set-xor char-set-diff+intersection
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;;; char-set-difference! char-set-xor! char-set-diff+intersection!
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;;;
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;;; char-set:lower-case char-set:upper-case char-set:title-case
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;;; char-set:letter char-set:digit char-set:letter+digit
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;;; char-set:graphic char-set:printing char-set:whitespace
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;;; char-set:iso-control char-set:punctuation char-set:symbol
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;;; char-set:hex-digit char-set:blank char-set:ascii
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;;; char-set:empty char-set:full
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;;; Imports
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;;; This code has the following non-R5RS dependencies:
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;;; - ERROR
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;;; - %LATIN1->CHAR %CHAR->LATIN1
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;;; - LET-OPTIONALS* and :OPTIONAL macros for parsing, checking & defaulting
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;;; optional arguments from rest lists.
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;;; - BITWISE-AND for CHAR-SET-HASH
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;;; - The SRFI-19 DEFINE-RECORD-TYPE record macro
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;;; - A simple CHECK-ARG procedure:
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;;; (lambda (pred val caller) (if (not (pred val)) (error val caller)))
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;;; This is simple code, not great code. Char sets are represented as 256-char
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;;; strings. If char I is ASCII/Latin-1 0, then it isn't in the set; if char I
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;;; is ASCII/Latin-1 1, then it is in the set.
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;;; - Should be rewritten to use bit strings or byte vecs.
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;;; - Is Latin-1 specific. Would certainly have to be rewritten for Unicode.
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;;; See the end of the file for porting and performance-tuning notes.
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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; Start S48 additions
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(define (check-arg pred val caller)
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(if (not (pred val))
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(error val caller))
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val)
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(define-syntax :optional
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(syntax-rules ()
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((:optional rest default-exp)
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(let ((maybe-arg rest))
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(if (pair? maybe-arg)
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(if (null? (cdr maybe-arg)) (car maybe-arg)
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(error "too many optional arguments" maybe-arg))
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default-exp)))
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((:optional rest default-exp arg-test)
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(let ((maybe-arg rest))
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(if (pair? maybe-arg)
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(if (null? (cdr maybe-arg))
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(let ((val (car maybe-arg)))
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(if (arg-test val) val
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(error "Optional argument failed test"
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'arg-test val)))
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(error "too many optional arguments" maybe-arg))
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default-exp)))))
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(define-syntax let-optionals*
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(syntax-rules ()
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((let-optionals* arg (opt-clause ...) body ...)
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(let ((rest arg))
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(%let-optionals* rest (opt-clause ...) body ...)))))
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(define-syntax %let-optionals*
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(syntax-rules ()
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((%let-optionals* arg (((var ...) xparser) opt-clause ...) body ...)
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(call-with-values (lambda () (xparser arg))
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(lambda (rest var ...)
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(%let-optionals* rest (opt-clause ...) body ...))))
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((%let-optionals* arg ((var default) opt-clause ...) body ...)
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(call-with-values (lambda () (if (null? arg) (values default '())
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(values (car arg) (cdr arg))))
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(lambda (var rest)
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(%let-optionals* rest (opt-clause ...) body ...))))
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((%let-optionals* arg ((var default test) opt-clause ...) body ...)
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(call-with-values (lambda ()
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(if (null? arg) (values default '())
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(let ((var (car arg)))
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(if test (values var (cdr arg))
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(error "arg failed LET-OPT test" var)))))
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(lambda (var rest)
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(%let-optionals* rest (opt-clause ...) body ...))))
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((%let-optionals* arg ((var default test supplied?) opt-clause ...) body ...)
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(call-with-values (lambda ()
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(if (null? arg) (values default #f '())
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(let ((var (car arg)))
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(if test (values var #t (cdr arg))
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(error "arg failed LET-OPT test" var)))))
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(lambda (var supplied? rest)
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(%let-optionals* rest (opt-clause ...) body ...))))
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((%let-optionals* arg (rest) body ...)
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(let ((rest arg)) body ...))
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((%let-optionals* arg () body ...)
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(if (null? arg) (begin body ...)
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(error "Too many arguments in let-opt" arg)))))
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; End S48 additions
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(define-record-type :char-set
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(make-char-set s)
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char-set?
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(s char-set:s))
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(define (%string-copy s) (substring s 0 (string-length s)))
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;;; Parse, type-check & default a final optional BASE-CS parameter from
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;;; a rest argument. Return a *fresh copy* of the underlying string.
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;;; The default is the empty set. The PROC argument is to help us
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;;; generate informative error exceptions.
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(define (%default-base maybe-base proc)
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(if (pair? maybe-base)
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(let ((bcs (car maybe-base))
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(tail (cdr maybe-base)))
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(if (null? tail)
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(if (char-set? bcs) (%string-copy (char-set:s bcs))
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(error "BASE-CS parameter not a char-set" proc bcs))
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(error "Expected final base char set -- too many parameters"
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proc maybe-base)))
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(make-string 256 (%latin1->char 0))))
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;;; If CS is really a char-set, do CHAR-SET:S, otw report an error msg on
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;;; behalf of our caller, PROC. This procedure exists basically to provide
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;;; explicit error-checking & reporting.
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(define (%char-set:s/check cs proc)
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(let lp ((cs cs))
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(if (char-set? cs) (char-set:s cs)
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(lp (error "Not a char-set" cs proc)))))
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;;; These internal functions hide a lot of the dependency on the
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;;; underlying string representation of char sets. They should be
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;;; inlined if possible.
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(define (si=0? s i) (zero? (%char->latin1 (string-ref s i))))
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(define (si=1? s i) (not (si=0? s i)))
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(define c0 (%latin1->char 0))
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(define c1 (%latin1->char 1))
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(define (si s i) (%char->latin1 (string-ref s i)))
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(define (%set0! s i) (string-set! s i c0))
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(define (%set1! s i) (string-set! s i c1))
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;;; These do various "s[i] := s[i] op val" operations -- see
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;;; %CHAR-SET-ALGEBRA. They are used to implement the various
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;;; set-algebra procedures.
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(define (setv! s i v) (string-set! s i (%latin1->char v))) ; SET to a Value.
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(define (%not! s i v) (setv! s i (- 1 v)))
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(define (%and! s i v) (if (zero? v) (%set0! s i)))
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(define (%or! s i v) (if (not (zero? v)) (%set1! s i)))
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(define (%minus! s i v) (if (not (zero? v)) (%set0! s i)))
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(define (%xor! s i v) (if (not (zero? v)) (setv! s i (- 1 (si s i)))))
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(define (char-set-copy cs)
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(make-char-set (%string-copy (%char-set:s/check cs char-set-copy))))
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(define (char-set= . rest)
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(or (null? rest)
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(let* ((cs1 (car rest))
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(rest (cdr rest))
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(s1 (%char-set:s/check cs1 char-set=)))
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(let lp ((rest rest))
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(or (not (pair? rest))
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(and (string=? s1 (%char-set:s/check (car rest) char-set=))
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(lp (cdr rest))))))))
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(define (char-set<= . rest)
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(or (null? rest)
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(let ((cs1 (car rest))
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(rest (cdr rest)))
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(let lp ((s1 (%char-set:s/check cs1 char-set<=)) (rest rest))
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(or (not (pair? rest))
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(let ((s2 (%char-set:s/check (car rest) char-set<=))
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(rest (cdr rest)))
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(if (eq? s1 s2) (lp s2 rest) ; Fast path
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(let lp2 ((i 255)) ; Real test
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(if (< i 0) (lp s2 rest)
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(and (<= (si s1 i) (si s2 i))
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(lp2 (- i 1))))))))))))
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;;; Hash
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;; Compute (c + 37 c + 37^2 c + ...) modulo BOUND, with sleaze thrown in
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;;; to keep the intermediate values small. (We do the calculation with just
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;;; enough bits to represent BOUND, masking off high bits at each step in
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;;; calculation. If this screws up any important properties of the hash
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;;; function I'd like to hear about it. -Olin)
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;;;
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;;; If you keep BOUND small enough, the intermediate calculations will
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;;; always be fixnums. How small is dependent on the underlying Scheme system;
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;;; we use a default BOUND of 2^22 = 4194304, which should hack it in
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;;; Schemes that give you at least 29 signed bits for fixnums. The core
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;;; calculation that you don't want to overflow is, worst case,
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;;; (+ 65535 (* 37 (- bound 1)))
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;;; where 65535 is the max character code. Choose the default BOUND to be the
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;;; biggest power of two that won't cause this expression to fixnum overflow,
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;;; and everything will be copacetic.
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(define (char-set-hash cs . maybe-bound)
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(let* ((bound (:optional maybe-bound 4194304 (lambda (n) (and (integer? n)
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(exact? n)
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(<= 0 n)))))
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(bound (if (zero? bound) 4194304 bound)) ; 0 means default.
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(s (%char-set:s/check cs char-set-hash))
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;; Compute a 111...1 mask that will cover BOUND-1:
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(mask (let lp ((i #x10000)) ; Let's skip first 16 iterations, eh?
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(if (>= i bound) (- i 1) (lp (+ i i))))))
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(let lp ((i 255) (ans 0))
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(if (< i 0) (modulo ans bound)
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(lp (- i 1)
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(if (si=0? s i) ans
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(bitwise-and mask (+ (* 37 ans) i))))))))
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(define (char-set-contains? cs char)
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(si=1? (%char-set:s/check cs char-set-contains?)
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(%char->latin1 (check-arg char? char char-set-contains?))))
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(define (char-set-size cs)
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(let ((s (%char-set:s/check cs char-set-size)))
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(let lp ((i 255) (size 0))
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(if (< i 0) size
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(lp (- i 1) (+ size (si s i)))))))
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(define (char-set-count pred cset)
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(check-arg procedure? pred char-set-count)
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(let ((s (%char-set:s/check cset char-set-count)))
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(let lp ((i 255) (count 0))
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(if (< i 0) count
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(lp (- i 1)
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(if (and (si=1? s i) (pred (%latin1->char i)))
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(+ count 1)
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count))))))
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;;; -- Adjoin & delete
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(define (%set-char-set set proc cs chars)
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(let ((s (%string-copy (%char-set:s/check cs proc))))
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(for-each (lambda (c) (set s (%char->latin1 c)))
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chars)
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(make-char-set s)))
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(define (%set-char-set! set proc cs chars)
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(let ((s (%char-set:s/check cs proc)))
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(for-each (lambda (c) (set s (%char->latin1 c)))
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chars))
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cs)
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(define (char-set-adjoin cs . chars)
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(%set-char-set %set1! char-set-adjoin cs chars))
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(define (char-set-adjoin! cs . chars)
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(%set-char-set! %set1! char-set-adjoin! cs chars))
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(define (char-set-delete cs . chars)
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(%set-char-set %set0! char-set-delete cs chars))
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(define (char-set-delete! cs . chars)
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(%set-char-set! %set0! char-set-delete! cs chars))
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;;; Cursors
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;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
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;;; Simple implementation. A cursors is an integer index into the
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;;; mark vector, and -1 for the end-of-char-set cursor.
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;;;
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;;; If we represented char sets as a bit set, we could do the following
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;;; trick to pick the lowest bit out of the set:
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;;; (count-bits (xor (- cset 1) cset))
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;;; (But first mask out the bits already scanned by the cursor first.)
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(define (char-set-cursor cset)
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(%char-set-cursor-next cset 256 char-set-cursor))
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(define (end-of-char-set? cursor) (< cursor 0))
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(define (char-set-ref cset cursor) (%latin1->char cursor))
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(define (char-set-cursor-next cset cursor)
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(check-arg (lambda (i) (and (integer? i) (exact? i) (<= 0 i 255))) cursor
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char-set-cursor-next)
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(%char-set-cursor-next cset cursor char-set-cursor-next))
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(define (%char-set-cursor-next cset cursor proc) ; Internal
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(let ((s (%char-set:s/check cset proc)))
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(let lp ((cur cursor))
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(let ((cur (- cur 1)))
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(if (or (< cur 0) (si=1? s cur)) cur
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(lp cur))))))
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;;; -- for-each map fold unfold every any
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(define (char-set-for-each proc cs)
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(check-arg procedure? proc char-set-for-each)
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(let ((s (%char-set:s/check cs char-set-for-each)))
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(let lp ((i 255))
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(cond ((>= i 0)
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(if (si=1? s i) (proc (%latin1->char i)))
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(lp (- i 1)))))))
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(define (char-set-map proc cs)
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(check-arg procedure? proc char-set-map)
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(let ((s (%char-set:s/check cs char-set-map))
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(ans (make-string 256 c0)))
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(let lp ((i 255))
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(cond ((>= i 0)
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(if (si=1? s i)
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(%set1! ans (%char->latin1 (proc (%latin1->char i)))))
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(lp (- i 1)))))
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(make-char-set ans)))
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(define (char-set-fold kons knil cs)
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(check-arg procedure? kons char-set-fold)
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(let ((s (%char-set:s/check cs char-set-fold)))
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(let lp ((i 255) (ans knil))
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(if (< i 0) ans
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(lp (- i 1)
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(if (si=0? s i) ans
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(kons (%latin1->char i) ans)))))))
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(define (char-set-every pred cs)
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(check-arg procedure? pred char-set-every)
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(let ((s (%char-set:s/check cs char-set-every)))
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(let lp ((i 255))
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(or (< i 0)
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(and (or (si=0? s i) (pred (%latin1->char i)))
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(lp (- i 1)))))))
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(define (char-set-any pred cs)
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(check-arg procedure? pred char-set-any)
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(let ((s (%char-set:s/check cs char-set-any)))
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(let lp ((i 255))
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(and (>= i 0)
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(or (and (si=1? s i) (pred (%latin1->char i)))
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(lp (- i 1)))))))
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(define (%char-set-unfold! proc p f g s seed)
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(check-arg procedure? p proc)
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(check-arg procedure? f proc)
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(check-arg procedure? g proc)
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(let lp ((seed seed))
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(cond ((not (p seed)) ; P says we are done.
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(%set1! s (%char->latin1 (f seed))) ; Add (F SEED) to set.
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(lp (g seed)))))) ; Loop on (G SEED).
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(define (char-set-unfold p f g seed . maybe-base)
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(let ((bs (%default-base maybe-base char-set-unfold)))
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(%char-set-unfold! char-set-unfold p f g bs seed)
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(make-char-set bs)))
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(define (char-set-unfold! p f g seed base-cset)
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(%char-set-unfold! char-set-unfold! p f g
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(%char-set:s/check base-cset char-set-unfold!)
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seed)
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base-cset)
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;;; list <--> char-set
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||
|
||
(define (%list->char-set! chars s)
|
||
(for-each (lambda (char) (%set1! s (%char->latin1 char)))
|
||
chars))
|
||
|
||
(define (char-set . chars)
|
||
(let ((s (make-string 256 c0)))
|
||
(%list->char-set! chars s)
|
||
(make-char-set s)))
|
||
|
||
(define (list->char-set chars . maybe-base)
|
||
(let ((bs (%default-base maybe-base list->char-set)))
|
||
(%list->char-set! chars bs)
|
||
(make-char-set bs)))
|
||
|
||
(define (list->char-set! chars base-cs)
|
||
(%list->char-set! chars (%char-set:s/check base-cs list->char-set!))
|
||
base-cs)
|
||
|
||
|
||
(define (char-set->list cs)
|
||
(let ((s (%char-set:s/check cs char-set->list)))
|
||
(let lp ((i 255) (ans '()))
|
||
(if (< i 0) ans
|
||
(lp (- i 1)
|
||
(if (si=0? s i) ans
|
||
(cons (%latin1->char i) ans)))))))
|
||
|
||
|
||
|
||
;;; string <--> char-set
|
||
|
||
(define (%string->char-set! str bs proc)
|
||
(check-arg string? str proc)
|
||
(do ((i (- (string-length str) 1) (- i 1)))
|
||
((< i 0))
|
||
(%set1! bs (%char->latin1 (string-ref str i)))))
|
||
|
||
(define (string->char-set str . maybe-base)
|
||
(let ((bs (%default-base maybe-base string->char-set)))
|
||
(%string->char-set! str bs string->char-set)
|
||
(make-char-set bs)))
|
||
|
||
(define (string->char-set! str base-cs)
|
||
(%string->char-set! str (%char-set:s/check base-cs string->char-set!)
|
||
string->char-set!)
|
||
base-cs)
|
||
|
||
|
||
(define (char-set->string cs)
|
||
(let* ((s (%char-set:s/check cs char-set->string))
|
||
(ans (make-string (char-set-size cs))))
|
||
(let lp ((i 255) (j 0))
|
||
(if (< i 0) ans
|
||
(let ((j (if (si=0? s i) j
|
||
(begin (string-set! ans j (%latin1->char i))
|
||
(+ j 1)))))
|
||
(lp (- i 1) j))))))
|
||
|
||
|
||
;;; -- UCS-range -> char-set
|
||
|
||
(define (%ucs-range->char-set! lower upper error? bs proc)
|
||
(check-arg (lambda (x) (and (integer? x) (exact? x) (<= 0 x))) lower proc)
|
||
(check-arg (lambda (x) (and (integer? x) (exact? x) (<= lower x))) upper proc)
|
||
|
||
(if (and (< lower upper) (< 256 upper) error?)
|
||
(error "Requested UCS range contains unavailable characters -- this implementation only supports Latin-1"
|
||
proc lower upper))
|
||
|
||
(let lp ((i (- (min upper 256) 1)))
|
||
(cond ((<= lower i) (%set1! bs i) (lp (- i 1))))))
|
||
|
||
(define (ucs-range->char-set lower upper . rest)
|
||
(let-optionals* rest ((error? #f) rest)
|
||
(let ((bs (%default-base rest ucs-range->char-set)))
|
||
(%ucs-range->char-set! lower upper error? bs ucs-range->char-set)
|
||
(make-char-set bs))))
|
||
|
||
(define (ucs-range->char-set! lower upper error? base-cs)
|
||
(%ucs-range->char-set! lower upper error?
|
||
(%char-set:s/check base-cs ucs-range->char-set!)
|
||
ucs-range->char-set)
|
||
base-cs)
|
||
|
||
|
||
;;; -- predicate -> char-set
|
||
|
||
(define (%char-set-filter! pred ds bs proc)
|
||
(check-arg procedure? pred proc)
|
||
(let lp ((i 255))
|
||
(cond ((>= i 0)
|
||
(if (and (si=1? ds i) (pred (%latin1->char i)))
|
||
(%set1! bs i))
|
||
(lp (- i 1))))))
|
||
|
||
(define (char-set-filter predicate domain . maybe-base)
|
||
(let ((bs (%default-base maybe-base char-set-filter)))
|
||
(%char-set-filter! predicate
|
||
(%char-set:s/check domain char-set-filter!)
|
||
bs
|
||
char-set-filter)
|
||
(make-char-set bs)))
|
||
|
||
(define (char-set-filter! predicate domain base-cs)
|
||
(%char-set-filter! predicate
|
||
(%char-set:s/check domain char-set-filter!)
|
||
(%char-set:s/check base-cs char-set-filter!)
|
||
char-set-filter!)
|
||
base-cs)
|
||
|
||
|
||
;;; {string, char, char-set} -> char-set
|
||
|
||
(define (x->char-set x)
|
||
(cond ((char-set? x) x)
|
||
((string? x) (string->char-set x))
|
||
((char? x) (char-set x))
|
||
(else (error "->char-set: Not a charset, string or char." x))))
|
||
|
||
|
||
|
||
;;; Set algebra
|
||
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||
;;; The exported ! procs are "linear update" -- allowed, but not required, to
|
||
;;; side-effect their first argument when computing their result. In other
|
||
;;; words, you must use them as if they were completely functional, just like
|
||
;;; their non-! counterparts, and you must additionally ensure that their
|
||
;;; first arguments are "dead" at the point of call. In return, we promise a
|
||
;;; more efficient result, plus allowing you to always assume char-sets are
|
||
;;; unchangeable values.
|
||
|
||
;;; Apply P to each index and its char code in S: (P I VAL).
|
||
;;; Used by the set-algebra ops.
|
||
|
||
(define (%string-iter p s)
|
||
(let lp ((i (- (string-length s) 1)))
|
||
(cond ((>= i 0)
|
||
(p i (%char->latin1 (string-ref s i)))
|
||
(lp (- i 1))))))
|
||
|
||
;;; String S represents some initial char-set. (OP s i val) does some
|
||
;;; kind of s[i] := s[i] op val update. Do
|
||
;;; S := S OP CSETi
|
||
;;; for all the char-sets in the list CSETS. The n-ary set-algebra ops
|
||
;;; all use this internal proc.
|
||
|
||
(define (%char-set-algebra s csets op proc)
|
||
(for-each (lambda (cset)
|
||
(let ((s2 (%char-set:s/check cset proc)))
|
||
(let lp ((i 255))
|
||
(cond ((>= i 0)
|
||
(op s i (si s2 i))
|
||
(lp (- i 1)))))))
|
||
csets))
|
||
|
||
|
||
;;; -- Complement
|
||
|
||
(define (char-set-complement cs)
|
||
(let ((s (%char-set:s/check cs char-set-complement))
|
||
(ans (make-string 256)))
|
||
(%string-iter (lambda (i v) (%not! ans i v)) s)
|
||
(make-char-set ans)))
|
||
|
||
(define (char-set-complement! cset)
|
||
(let ((s (%char-set:s/check cset char-set-complement!)))
|
||
(%string-iter (lambda (i v) (%not! s i v)) s))
|
||
cset)
|
||
|
||
|
||
;;; -- Union
|
||
|
||
(define (char-set-union! cset1 . csets)
|
||
(%char-set-algebra (%char-set:s/check cset1 char-set-union!)
|
||
csets %or! char-set-union!)
|
||
cset1)
|
||
|
||
(define (char-set-union . csets)
|
||
(if (pair? csets)
|
||
(let ((s (%string-copy (%char-set:s/check (car csets) char-set-union))))
|
||
(%char-set-algebra s (cdr csets) %or! char-set-union)
|
||
(make-char-set s))
|
||
(char-set-copy char-set:empty)))
|
||
|
||
|
||
;;; -- Intersection
|
||
|
||
(define (char-set-intersection! cset1 . csets)
|
||
(%char-set-algebra (%char-set:s/check cset1 char-set-intersection!)
|
||
csets %and! char-set-intersection!)
|
||
cset1)
|
||
|
||
(define (char-set-intersection . csets)
|
||
(if (pair? csets)
|
||
(let ((s (%string-copy (%char-set:s/check (car csets) char-set-intersection))))
|
||
(%char-set-algebra s (cdr csets) %and! char-set-intersection)
|
||
(make-char-set s))
|
||
(char-set-copy char-set:full)))
|
||
|
||
|
||
;;; -- Difference
|
||
|
||
(define (char-set-difference! cset1 . csets)
|
||
(%char-set-algebra (%char-set:s/check cset1 char-set-difference!)
|
||
csets %minus! char-set-difference!)
|
||
cset1)
|
||
|
||
(define (char-set-difference cs1 . csets)
|
||
(if (pair? csets)
|
||
(let ((s (%string-copy (%char-set:s/check cs1 char-set-difference))))
|
||
(%char-set-algebra s csets %minus! char-set-difference)
|
||
(make-char-set s))
|
||
(char-set-copy cs1)))
|
||
|
||
|
||
;;; -- Xor
|
||
|
||
(define (char-set-xor! cset1 . csets)
|
||
(%char-set-algebra (%char-set:s/check cset1 char-set-xor!)
|
||
csets %xor! char-set-xor!)
|
||
cset1)
|
||
|
||
(define (char-set-xor . csets)
|
||
(if (pair? csets)
|
||
(let ((s (%string-copy (%char-set:s/check (car csets) char-set-xor))))
|
||
(%char-set-algebra s (cdr csets) %xor! char-set-xor)
|
||
(make-char-set s))
|
||
(char-set-copy char-set:empty)))
|
||
|
||
|
||
;;; -- Difference & intersection
|
||
|
||
(define (%char-set-diff+intersection! diff int csets proc)
|
||
(for-each (lambda (cs)
|
||
(%string-iter (lambda (i v)
|
||
(if (not (zero? v))
|
||
(cond ((si=1? diff i)
|
||
(%set0! diff i)
|
||
(%set1! int i)))))
|
||
(%char-set:s/check cs proc)))
|
||
csets))
|
||
|
||
(define (char-set-diff+intersection! cs1 cs2 . csets)
|
||
(let ((s1 (%char-set:s/check cs1 char-set-diff+intersection!))
|
||
(s2 (%char-set:s/check cs2 char-set-diff+intersection!)))
|
||
(%string-iter (lambda (i v) (if (zero? v)
|
||
(%set0! s2 i)
|
||
(if (si=1? s2 i) (%set0! s1 i))))
|
||
s1)
|
||
(%char-set-diff+intersection! s1 s2 csets char-set-diff+intersection!))
|
||
(values cs1 cs2))
|
||
|
||
(define (char-set-diff+intersection cs1 . csets)
|
||
(let ((diff (string-copy (%char-set:s/check cs1 char-set-diff+intersection)))
|
||
(int (make-string 256 c0)))
|
||
(%char-set-diff+intersection! diff int csets char-set-diff+intersection)
|
||
(values (make-char-set diff) (make-char-set int))))
|
||
|
||
|
||
;;;; System character sets
|
||
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||
;;; These definitions are for Latin-1.
|
||
;;;
|
||
;;; If your Scheme implementation allows you to mark the underlying strings
|
||
;;; as immutable, you should do so -- it would be very, very bad if a client's
|
||
;;; buggy code corrupted these constants.
|
||
|
||
(define char-set:empty (char-set))
|
||
(define char-set:full (char-set-complement char-set:empty))
|
||
|
||
(define char-set:lower-case
|
||
(let* ((a-z (ucs-range->char-set #x61 #x7B))
|
||
(latin1 (ucs-range->char-set! #xdf #xf7 #t a-z))
|
||
(latin2 (ucs-range->char-set! #xf8 #x100 #t latin1)))
|
||
(char-set-adjoin! latin2 (%latin1->char #xb5))))
|
||
|
||
(define char-set:upper-case
|
||
(let ((A-Z (ucs-range->char-set #x41 #x5B)))
|
||
;; Add in the Latin-1 upper-case chars.
|
||
(ucs-range->char-set! #xd8 #xdf #t
|
||
(ucs-range->char-set! #xc0 #xd7 #t A-Z))))
|
||
|
||
(define char-set:title-case char-set:empty)
|
||
|
||
(define char-set:letter
|
||
(let ((u/l (char-set-union char-set:upper-case char-set:lower-case)))
|
||
(char-set-adjoin! u/l
|
||
(%latin1->char #xaa) ; FEMININE ORDINAL INDICATOR
|
||
(%latin1->char #xba)))) ; MASCULINE ORDINAL INDICATOR
|
||
|
||
(define char-set:digit (string->char-set "0123456789"))
|
||
(define char-set:hex-digit (string->char-set "0123456789abcdefABCDEF"))
|
||
|
||
(define char-set:letter+digit
|
||
(char-set-union char-set:letter char-set:digit))
|
||
|
||
(define char-set:punctuation
|
||
(let ((ascii (string->char-set "!\"#%&'()*,-./:;?@[\\]_{}"))
|
||
(latin-1-chars (map %latin1->char '(#xA1 ; INVERTED EXCLAMATION MARK
|
||
#xAB ; LEFT-POINTING DOUBLE ANGLE QUOTATION MARK
|
||
#xAD ; SOFT HYPHEN
|
||
#xB7 ; MIDDLE DOT
|
||
#xBB ; RIGHT-POINTING DOUBLE ANGLE QUOTATION MARK
|
||
#xBF)))) ; INVERTED QUESTION MARK
|
||
(list->char-set! latin-1-chars ascii)))
|
||
|
||
(define char-set:symbol
|
||
(let ((ascii (string->char-set "$+<=>^`|~"))
|
||
(latin-1-chars (map %latin1->char '(#x00A2 ; CENT SIGN
|
||
#x00A3 ; POUND SIGN
|
||
#x00A4 ; CURRENCY SIGN
|
||
#x00A5 ; YEN SIGN
|
||
#x00A6 ; BROKEN BAR
|
||
#x00A7 ; SECTION SIGN
|
||
#x00A8 ; DIAERESIS
|
||
#x00A9 ; COPYRIGHT SIGN
|
||
#x00AC ; NOT SIGN
|
||
#x00AE ; REGISTERED SIGN
|
||
#x00AF ; MACRON
|
||
#x00B0 ; DEGREE SIGN
|
||
#x00B1 ; PLUS-MINUS SIGN
|
||
#x00B4 ; ACUTE ACCENT
|
||
#x00B6 ; PILCROW SIGN
|
||
#x00B8 ; CEDILLA
|
||
#x00D7 ; MULTIPLICATION SIGN
|
||
#x00F7)))) ; DIVISION SIGN
|
||
(list->char-set! latin-1-chars ascii)))
|
||
|
||
|
||
(define char-set:graphic
|
||
(char-set-union char-set:letter+digit char-set:punctuation char-set:symbol))
|
||
|
||
(define char-set:whitespace
|
||
(list->char-set (map %latin1->char '(#x09 ; HORIZONTAL TABULATION
|
||
#x0A ; LINE FEED
|
||
#x0B ; VERTICAL TABULATION
|
||
#x0C ; FORM FEED
|
||
#x0D ; CARRIAGE RETURN
|
||
#x20 ; SPACE
|
||
#xA0))))
|
||
|
||
(define char-set:printing (char-set-union char-set:whitespace char-set:graphic)) ; NO-BREAK SPACE
|
||
|
||
(define char-set:blank
|
||
(list->char-set (map %latin1->char '(#x09 ; HORIZONTAL TABULATION
|
||
#x20 ; SPACE
|
||
#xA0)))) ; NO-BREAK SPACE
|
||
|
||
|
||
(define char-set:iso-control
|
||
(ucs-range->char-set! #x7F #xA0 #t (ucs-range->char-set 0 32)))
|
||
|
||
(define char-set:ascii (ucs-range->char-set 0 128))
|
||
|
||
; Begin S48 additions
|
||
|
||
(define (make-char-set-immutable! char-set)
|
||
(make-immutable! char-set)
|
||
(make-immutable! (char-set:s char-set)))
|
||
|
||
(make-char-set-immutable! char-set:empty)
|
||
(make-char-set-immutable! char-set:full)
|
||
(make-char-set-immutable! char-set:lower-case)
|
||
(make-char-set-immutable! char-set:upper-case)
|
||
(make-char-set-immutable! char-set:letter)
|
||
(make-char-set-immutable! char-set:digit)
|
||
(make-char-set-immutable! char-set:hex-digit)
|
||
(make-char-set-immutable! char-set:letter+digit)
|
||
(make-char-set-immutable! char-set:punctuation)
|
||
(make-char-set-immutable! char-set:symbol)
|
||
(make-char-set-immutable! char-set:graphic)
|
||
(make-char-set-immutable! char-set:whitespace)
|
||
(make-char-set-immutable! char-set:printing)
|
||
(make-char-set-immutable! char-set:blank)
|
||
(make-char-set-immutable! char-set:iso-control)
|
||
(make-char-set-immutable! char-set:ascii)
|
||
|
||
; End S48 additions
|
||
|
||
|
||
;;; Porting & performance-tuning notes
|
||
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
|
||
;;; See the section at the beginning of this file on external dependencies.
|
||
;;;
|
||
;;; First and foremost, rewrite this code to use bit vectors of some sort.
|
||
;;; This will give big speedup and memory savings.
|
||
;;;
|
||
;;; - LET-OPTIONALS* macro.
|
||
;;; This is only used once. You can rewrite the use, port the hairy macro
|
||
;;; definition (which is implemented using a Clinger-Rees low-level
|
||
;;; explicit-renaming macro system), or port the simple, high-level
|
||
;;; definition, which is less efficient.
|
||
;;;
|
||
;;; - :OPTIONAL macro
|
||
;;; Very simply defined using an R5RS high-level macro.
|
||
;;;
|
||
;;; Implementations that can arrange for the base char sets to be immutable
|
||
;;; should do so. (E.g., Scheme 48 allows one to mark a string as immutable,
|
||
;;; which can be used to protect the underlying strings.) It would be very,
|
||
;;; very bad if a client's buggy code corrupted these constants.
|
||
;;;
|
||
;;; There is a fair amount of argument checking. This is, strictly speaking,
|
||
;;; unnecessary -- the actual body of the procedures will blow up if an
|
||
;;; illegal value is passed in. However, the error message will not be as good
|
||
;;; as if the error were caught at the "higher level." Also, a very, very
|
||
;;; smart Scheme compiler may be able to exploit having the type checks done
|
||
;;; early, so that the actual body of the procedures can assume proper values.
|
||
;;; This isn't likely; this kind of compiler technology isn't common any
|
||
;;; longer.
|
||
;;;
|
||
;;; The overhead of optional-argument parsing is irritating. The optional
|
||
;;; arguments must be consed into a rest list on entry, and then parsed out.
|
||
;;; Function call should be a matter of a few register moves and a jump; it
|
||
;;; should not involve heap allocation! Your Scheme system may have a superior
|
||
;;; non-R5RS optional-argument system that can eliminate this overhead. If so,
|
||
;;; then this is a prime candidate for optimising these procedures,
|
||
;;; *especially* the many optional BASE-CS parameters.
|
||
;;;
|
||
;;; Note that optional arguments are also a barrier to procedure integration.
|
||
;;; If your Scheme system permits you to specify alternate entry points
|
||
;;; for a call when the number of optional arguments is known in a manner
|
||
;;; that enables inlining/integration, this can provide performance
|
||
;;; improvements.
|
||
;;;
|
||
;;; There is enough *explicit* error checking that *all* internal operations
|
||
;;; should *never* produce a type or index-range error. Period. Feel like
|
||
;;; living dangerously? *Big* performance win to be had by replacing string
|
||
;;; and record-field accessors and setters with unsafe equivalents in the
|
||
;;; code. Similarly, fixnum-specific operators can speed up the arithmetic
|
||
;;; done on the index values in the inner loops. The only arguments that are
|
||
;;; not completely error checked are
|
||
;;; - string lists (complete checking requires time proportional to the
|
||
;;; length of the list)
|
||
;;; - procedure arguments, such as char->char maps & predicates.
|
||
;;; There is no way to check the range & domain of procedures in Scheme.
|
||
;;; Procedures that take these parameters cannot fully check their
|
||
;;; arguments. But all other types to all other procedures are fully
|
||
;;; checked.
|
||
;;;
|
||
;;; This does open up the alternate possibility of simply *removing* these
|
||
;;; checks, and letting the safe primitives raise the errors. On a dumb
|
||
;;; Scheme system, this would provide speed (by eliminating the redundant
|
||
;;; error checks) at the cost of error-message clarity.
|
||
;;;
|
||
;;; In an interpreted Scheme, some of these procedures, or the internal
|
||
;;; routines with % prefixes, are excellent candidates for being rewritten
|
||
;;; in C.
|
||
;;;
|
||
;;; It would also be nice to have the ability to mark some of these
|
||
;;; routines as candidates for inlining/integration.
|
||
;;;
|
||
;;; See the comments preceding the hash function code for notes on tuning
|
||
;;; the default bound so that the code never overflows your implementation's
|
||
;;; fixnum size into bignum calculation.
|
||
;;;
|
||
;;; All the %-prefixed routines in this source code are written
|
||
;;; to be called internally to this library. They do *not* perform
|
||
;;; friendly error checks on the inputs; they assume everything is
|
||
;;; proper. They also do not take optional arguments. These two properties
|
||
;;; save calling overhead and enable procedure integration -- but they
|
||
;;; are not appropriate for exported routines.
|
||
|
||
|
||
;;; The MIT Scheme project gave Olin Shivers the permission to use the
|
||
;;; code from this SRFI under the following license:
|
||
;;;
|
||
;;; Redistribution and use in source and binary forms, with or without
|
||
;;; modification, are permitted provided that the following conditions are
|
||
;;; met:
|
||
;;;
|
||
;;; 1. Redistributions of source code must retain the above copyright
|
||
;;; notice, this list of conditions and the following disclaimer.
|
||
;;;
|
||
;;; 2. Redistributions in binary form must reproduce the above
|
||
;;; copyright notice, this list of conditions and the following
|
||
;;; disclaimer in the documentation and/or other materials provided
|
||
;;; with the distribution.
|
||
;;;
|
||
;;; 3. The name of the author may not be used to endorse or promote
|
||
;;; products derived from this software without specific prior
|
||
;;; written permission.
|
||
;;;
|
||
;;; THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
|
||
;;; IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
|
||
;;; WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
|
||
;;; DISCLAIMED. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT,
|
||
;;; INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
|
||
;;; (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
|
||
;;; SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
|
||
;;; HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT,
|
||
;;; STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING
|
||
;;; IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
|
||
;;; POSSIBILITY OF SUCH DAMAGE. |