524 lines
20 KiB
Common Lisp
524 lines
20 KiB
Common Lisp
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;;;
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;;; This code was written by:
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;;;
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;;; Lawrence E. Freil <lef@freil.com>
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;;; National Science Center Foundation
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;;; Augusta, Georgia 30909
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;;;
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;;; This program was released into the public domain on 2005-08-31.
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;;; (See the slime-devel mailing list archive for details.)
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;;;
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;;; nregex.lisp - My 4/8/92 attempt at a Lisp based regular expression
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;;; parser.
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;;;
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;;; This regular expression parser operates by taking a
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;;; regular expression and breaking it down into a list
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;;; consisting of lisp expressions and flags. The list
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;;; of lisp expressions is then taken in turned into a
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;;; lambda expression that can be later applied to a
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;;; string argument for parsing.
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;;;;
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;;;; Modifications made 6 March 2001 By Chris Double (chris@double.co.nz)
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;;;; to get working with Corman Lisp 1.42, add package statement and export
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;;;; relevant functions.
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;;;;
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(in-package :cl-user)
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;; Renamed to slime-nregex avoid name clashes with other versions of
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;; this file. -- he
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;;;; CND - 6/3/2001
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(defpackage slime-nregex
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(:use #:common-lisp)
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(:export
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#:regex
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#:regex-compile
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))
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;;;; CND - 6/3/2001
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(in-package :slime-nregex)
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;;;
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;;; First we create a copy of macros to help debug the beast
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(eval-when (:compile-toplevel :load-toplevel :execute)
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(defvar *regex-debug* nil) ; Set to nil for no debugging code
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)
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(defmacro info (message &rest args)
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(if *regex-debug*
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`(format *standard-output* ,message ,@args)))
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;;;
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;;; Declare the global variables for storing the paren index list.
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;;;
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(defvar *regex-groups* (make-array 10))
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(defvar *regex-groupings* 0)
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;;;
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;;; Declare a simple interface for testing. You probably wouldn't want
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;;; to use this interface unless you were just calling this once.
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;;;
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(defun regex (expression string)
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"Usage: (regex <expression> <string)
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This function will call regex-compile on the expression and then apply
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the string to the returned lambda list."
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(let ((findit (cond ((stringp expression)
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(regex-compile expression))
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((listp expression)
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expression)))
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(result nil))
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(if (not (funcall (if (functionp findit)
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findit
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(eval `(function ,findit))) string))
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(return-from regex nil))
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(if (= *regex-groupings* 0)
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(return-from regex t))
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(dotimes (i *regex-groupings*)
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(push (funcall 'subseq
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string
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(car (aref *regex-groups* i))
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(cadr (aref *regex-groups* i)))
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result))
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(reverse result)))
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;;;
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;;; Declare some simple macros to make the code more readable.
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;;;
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(defvar *regex-special-chars* "?*+.()[]\\${}")
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(defmacro add-exp (list)
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"Add an item to the end of expression"
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`(setf expression (append expression ,list)))
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;;;
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;;; Define a function that will take a quoted character and return
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;;; what the real character should be plus how much of the source
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;;; string was used. If the result is a set of characters, return an
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;;; array of bits indicating which characters should be set. If the
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;;; expression is one of the sub-group matches return a
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;;; list-expression that will provide the match.
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;;;
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(defun regex-quoted (char-string &optional (invert nil))
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"Usage: (regex-quoted <char-string> &optional invert)
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Returns either the quoted character or a simple bit vector of bits set for
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the matching values"
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(let ((first (char char-string 0))
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(result (char char-string 0))
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(used-length 1))
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(cond ((eql first #\n)
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(setf result #\NewLine))
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((eql first #\c)
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(setf result #\Return))
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((eql first #\t)
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(setf result #\Tab))
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((eql first #\d)
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(setf result #*0000000000000000000000000000000000000000000000001111111111000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000))
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((eql first #\D)
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(setf result #*1111111111111111111111111111111111111111111111110000000000111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111))
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((eql first #\w)
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(setf result #*0000000000000000000000000000000000000000000000001111111111000000011111111111111111111111111000010111111111111111111111111110000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000))
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((eql first #\W)
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(setf result #*1111111111111111111111111111111111111111111111110000000000111111100000000000000000000000000111101000000000000000000000000001111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111))
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((eql first #\b)
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(setf result #*0000000001000000000000000000000011000000000010100000000000100000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000))
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((eql first #\B)
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(setf result #*1111111110111111111111111111111100111111111101011111111111011111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111))
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((eql first #\s)
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(setf result #*0000000001100000000000000000000010000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000))
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((eql first #\S)
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(setf result #*1111111110011111111111111111111101111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111))
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((and (>= (char-code first) (char-code #\0))
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(<= (char-code first) (char-code #\9)))
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(if (and (> (length char-string) 2)
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(and (>= (char-code (char char-string 1)) (char-code #\0))
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(<= (char-code (char char-string 1)) (char-code #\9))
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(>= (char-code (char char-string 2)) (char-code #\0))
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(<= (char-code (char char-string 2)) (char-code #\9))))
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;;
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;; It is a single character specified in octal
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;;
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(progn
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(setf result (do ((x 0 (1+ x))
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(return 0))
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((= x 2) return)
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(setf return (+ (* return 8)
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(- (char-code (char char-string x))
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(char-code #\0))))))
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(setf used-length 3))
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;;
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;; We have a group number replacement.
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;;
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(let ((group (- (char-code first) (char-code #\0))))
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(setf result `((let ((nstring (subseq string (car (aref *regex-groups* ,group))
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(cadr (aref *regex-groups* ,group)))))
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(if (< length (+ index (length nstring)))
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(return-from compare nil))
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(if (not (string= string nstring
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:start1 index
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:end1 (+ index (length nstring))))
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(return-from compare nil)
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(incf index (length nstring)))))))))
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(t
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(setf result first)))
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(if (and (vectorp result) invert)
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(bit-xor result #*1111111110011111111111111111111101111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111111 t))
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(values result used-length)))
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;;;
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;;; Now for the main regex compiler routine.
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;;;
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(defun regex-compile (source &key (anchored nil))
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"Usage: (regex-compile <expression> [ :anchored (t/nil) ])
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This function take a regular expression (supplied as source) and
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compiles this into a lambda list that a string argument can then
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be applied to. It is also possible to compile this lambda list
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for better performance or to save it as a named function for later
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use"
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(info "Now entering regex-compile with \"~A\"~%" source)
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;;
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;; This routine works in two parts.
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;; The first pass take the regular expression and produces a list of
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;; operators and lisp expressions for the entire regular expression.
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;; The second pass takes this list and produces the lambda expression.
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(let ((expression '()) ; holder for expressions
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(group 1) ; Current group index
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(group-stack nil) ; Stack of current group endings
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(result nil) ; holder for built expression.
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(fast-first nil)) ; holder for quick unanchored scan
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;;
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;; If the expression was an empty string then it alway
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;; matches (so lets leave early)
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;;
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(if (= (length source) 0)
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(return-from regex-compile
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'(lambda (&rest args)
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(declare (ignore args))
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t)))
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;;
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;; If the first character is a caret then set the anchored
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;; flags and remove if from the expression string.
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;;
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(cond ((eql (char source 0) #\^)
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(setf source (subseq source 1))
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(setf anchored t)))
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;;
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;; If the first sequence is .* then also set the anchored flags.
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;; (This is purely for optimization, it will work without this).
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;;
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(if (>= (length source) 2)
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(if (string= source ".*" :start1 0 :end1 2)
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(setf anchored t)))
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;;
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;; Also, If this is not an anchored search and the first character is
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;; a literal, then do a quick scan to see if it is even in the string.
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;; If not then we can issue a quick nil,
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;; otherwise we can start the search at the matching character to skip
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;; the checks of the non-matching characters anyway.
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;;
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;; If I really wanted to speed up this section of code it would be
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;; easy to recognize the case of a fairly long multi-character literal
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;; and generate a Boyer-Moore search for the entire literal.
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;;
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;; I generate the code to do a loop because on CMU Lisp this is about
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;; twice as fast a calling position.
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;;
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(if (and (not anchored)
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(not (position (char source 0) *regex-special-chars*))
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(not (and (> (length source) 1)
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(position (char source 1) *regex-special-chars*))))
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(setf fast-first `((if (not (dotimes (i length nil)
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(if (eql (char string i)
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,(char source 0))
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(return (setf start i)))))
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(return-from final-return nil)))))
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;;
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;; Generate the very first expression to save the starting index
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;; so that group 0 will be the entire string matched always
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;;
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(add-exp '((setf (aref *regex-groups* 0)
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(list index nil))))
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;;
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;; Loop over each character in the regular expression building the
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;; expression list as we go.
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;;
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(do ((eindex 0 (1+ eindex)))
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((= eindex (length source)))
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(let ((current (char source eindex)))
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(info "Now processing character ~A index = ~A~%" current eindex)
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(case current
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((#\.)
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;;
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;; Generate code for a single wild character
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;;
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(add-exp '((if (>= index length)
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(return-from compare nil)
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(incf index)))))
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((#\$)
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;;
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;; If this is the last character of the expression then
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;; anchor the end of the expression, otherwise let it slide
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;; as a standard character (even though it should be quoted).
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;;
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(if (= eindex (1- (length source)))
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(add-exp '((if (not (= index length))
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(return-from compare nil))))
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(add-exp '((if (not (and (< index length)
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(eql (char string index) #\$)))
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(return-from compare nil)
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(incf index))))))
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((#\*)
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(add-exp '(ASTRISK)))
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((#\+)
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(add-exp '(PLUS)))
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((#\?)
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(add-exp '(QUESTION)))
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((#\()
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;;
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;; Start a grouping.
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;;
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(incf group)
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(push group group-stack)
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(add-exp `((setf (aref *regex-groups* ,(1- group))
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(list index nil))))
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(add-exp `(,group)))
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((#\))
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;;
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;; End a grouping
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;;
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(let ((group (pop group-stack)))
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(add-exp `((setf (cadr (aref *regex-groups* ,(1- group)))
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index)))
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(add-exp `(,(- group)))))
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((#\[)
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;;
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;; Start of a range operation.
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;; Generate a bit-vector that has one bit per possible character
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;; and then on each character or range, set the possible bits.
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;;
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;; If the first character is carat then invert the set.
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(let* ((invert (eql (char source (1+ eindex)) #\^))
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(bitstring (make-array 256 :element-type 'bit
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:initial-element
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(if invert 1 0)))
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(set-char (if invert 0 1)))
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(if invert (incf eindex))
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(do ((x (1+ eindex) (1+ x)))
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((eql (char source x) #\]) (setf eindex x))
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(info "Building range with character ~A~%" (char source x))
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(cond ((and (eql (char source (1+ x)) #\-)
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(not (eql (char source (+ x 2)) #\])))
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(if (>= (char-code (char source x))
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(char-code (char source (+ 2 x))))
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(error "Invalid range \"~A-~A\". Ranges must be in acending order"
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(char source x) (char source (+ 2 x))))
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(do ((j (char-code (char source x)) (1+ j)))
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((> j (char-code (char source (+ 2 x))))
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(incf x 2))
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(info "Setting bit for char ~A code ~A~%" (code-char j) j)
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(setf (sbit bitstring j) set-char)))
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(t
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(cond ((not (eql (char source x) #\]))
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(let ((char (char source x)))
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;;
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;; If the character is quoted then find out what
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;; it should have been
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;;
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(if (eql (char source x) #\\ )
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(let ((length))
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(multiple-value-setq (char length)
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(regex-quoted (subseq source x) invert))
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(incf x length)))
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(info "Setting bit for char ~A code ~A~%" char (char-code char))
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(if (not (vectorp char))
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(setf (sbit bitstring (char-code (char source x))) set-char)
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(bit-ior bitstring char t))))))))
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(add-exp `((let ((range ,bitstring))
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(if (>= index length)
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(return-from compare nil))
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(if (= 1 (sbit range (char-code (char string index))))
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(incf index)
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(return-from compare nil)))))))
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((#\\ )
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;;
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;; Intreprete the next character as a special, range, octal, group or
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;; just the character itself.
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;;
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(let ((length)
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(value))
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(multiple-value-setq (value length)
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(regex-quoted (subseq source (1+ eindex)) nil))
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(cond ((listp value)
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(add-exp value))
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((characterp value)
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(add-exp `((if (not (and (< index length)
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(eql (char string index)
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,value)))
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(return-from compare nil)
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(incf index)))))
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((vectorp value)
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(add-exp `((let ((range ,value))
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(if (>= index length)
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(return-from compare nil))
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(if (= 1 (sbit range (char-code (char string index))))
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(incf index)
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(return-from compare nil)))))))
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(incf eindex length)))
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(t
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;;
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;; We have a literal character.
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;; Scan to see how many we have and if it is more than one
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;; generate a string= verses as single eql.
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;;
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(let* ((lit "")
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(term (dotimes (litindex (- (length source) eindex) nil)
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(let ((litchar (char source (+ eindex litindex))))
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(if (position litchar *regex-special-chars*)
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(return litchar)
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(progn
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(info "Now adding ~A index ~A to lit~%" litchar
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litindex)
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(setf lit (concatenate 'string lit
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(string litchar)))))))))
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(if (= (length lit) 1)
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(add-exp `((if (not (and (< index length)
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(eql (char string index) ,current)))
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(return-from compare nil)
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(incf index))))
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;;
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;; If we have a multi-character literal then we must
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;; check to see if the next character (if there is one)
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;; is an astrisk or a plus or a question mark. If so then we must not use this
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;; character in the big literal.
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(progn
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(if (or (eql term #\*)
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(eql term #\+)
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(eql term #\?))
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(setf lit (subseq lit 0 (1- (length lit)))))
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(add-exp `((if (< length (+ index ,(length lit)))
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(return-from compare nil))
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(if (not (string= string ,lit :start1 index
|
||
|
:end1 (+ index ,(length lit))))
|
||
|
(return-from compare nil)
|
||
|
(incf index ,(length lit)))))))
|
||
|
(incf eindex (1- (length lit))))))))
|
||
|
;;
|
||
|
;; Plug end of list to return t. If we made it this far then
|
||
|
;; We have matched!
|
||
|
(add-exp '((setf (cadr (aref *regex-groups* 0))
|
||
|
index)))
|
||
|
(add-exp '((return-from final-return t)))
|
||
|
;;
|
||
|
;;; (print expression)
|
||
|
;;
|
||
|
;; Now take the expression list and turn it into a lambda expression
|
||
|
;; replacing the special flags with lisp code.
|
||
|
;; For example: A BEGIN needs to be replace by an expression that
|
||
|
;; saves the current index, then evaluates everything till it gets to
|
||
|
;; the END then save the new index if it didn't fail.
|
||
|
;; On an ASTRISK I need to take the previous expression and wrap
|
||
|
;; it in a do that will evaluate the expression till an error
|
||
|
;; occurs and then another do that encompases the remainder of the
|
||
|
;; regular expression and iterates decrementing the index by one
|
||
|
;; of the matched expression sizes and then returns nil. After
|
||
|
;; the last expression insert a form that does a return t so that
|
||
|
;; if the entire nested sub-expression succeeds then the loop
|
||
|
;; is broken manually.
|
||
|
;;
|
||
|
(setf result (copy-tree nil))
|
||
|
;;
|
||
|
;; Reversing the current expression makes building up the
|
||
|
;; lambda list easier due to the nexting of expressions when
|
||
|
;; and astrisk has been encountered.
|
||
|
(setf expression (reverse expression))
|
||
|
(do ((elt 0 (1+ elt)))
|
||
|
((>= elt (length expression)))
|
||
|
(let ((piece (nth elt expression)))
|
||
|
;;
|
||
|
;; Now check for PLUS, if so then ditto the expression and then let the
|
||
|
;; ASTRISK below handle the rest.
|
||
|
;;
|
||
|
(cond ((eql piece 'PLUS)
|
||
|
(cond ((listp (nth (1+ elt) expression))
|
||
|
(setf result (append (list (nth (1+ elt) expression))
|
||
|
result)))
|
||
|
;;
|
||
|
;; duplicate the entire group
|
||
|
;; NOTE: This hasn't been implemented yet!!
|
||
|
(t
|
||
|
(error "GROUP repeat hasn't been implemented yet~%")))))
|
||
|
(cond ((listp piece) ;Just append the list
|
||
|
(setf result (append (list piece) result)))
|
||
|
((eql piece 'QUESTION) ; Wrap it in a block that won't fail
|
||
|
(cond ((listp (nth (1+ elt) expression))
|
||
|
(setf result
|
||
|
(append `((progn (block compare
|
||
|
,(nth (1+ elt)
|
||
|
expression))
|
||
|
t))
|
||
|
result))
|
||
|
(incf elt))
|
||
|
;;
|
||
|
;; This is a QUESTION on an entire group which
|
||
|
;; hasn't been implemented yet!!!
|
||
|
;;
|
||
|
(t
|
||
|
(error "Optional groups not implemented yet~%"))))
|
||
|
((or (eql piece 'ASTRISK) ; Do the wild thing!
|
||
|
(eql piece 'PLUS))
|
||
|
(cond ((listp (nth (1+ elt) expression))
|
||
|
;;
|
||
|
;; This is a single character wild card so
|
||
|
;; do the simple form.
|
||
|
;;
|
||
|
(setf result
|
||
|
`((let ((oindex index))
|
||
|
(block compare
|
||
|
(do ()
|
||
|
(nil)
|
||
|
,(nth (1+ elt) expression)))
|
||
|
(do ((start index (1- start)))
|
||
|
((< start oindex) nil)
|
||
|
(let ((index start))
|
||
|
(block compare
|
||
|
,@result))))))
|
||
|
(incf elt))
|
||
|
(t
|
||
|
;;
|
||
|
;; This is a subgroup repeated so I must build
|
||
|
;; the loop using several values.
|
||
|
;;
|
||
|
))
|
||
|
)
|
||
|
(t t)))) ; Just ignore everything else.
|
||
|
;;
|
||
|
;; Now wrap the result in a lambda list that can then be
|
||
|
;; invoked or compiled, however the user wishes.
|
||
|
;;
|
||
|
(if anchored
|
||
|
(setf result
|
||
|
`(lambda (string &key (start 0) (end (length string)))
|
||
|
(setf *regex-groupings* ,group)
|
||
|
(block final-return
|
||
|
(block compare
|
||
|
(let ((index start)
|
||
|
(length end))
|
||
|
,@result)))))
|
||
|
(setf result
|
||
|
`(lambda (string &key (start 0) (end (length string)))
|
||
|
(setf *regex-groupings* ,group)
|
||
|
(block final-return
|
||
|
(let ((length end))
|
||
|
,@fast-first
|
||
|
(do ((marker start (1+ marker)))
|
||
|
((> marker end) nil)
|
||
|
(let ((index marker))
|
||
|
(if (block compare
|
||
|
,@result)
|
||
|
(return t)))))))))))
|
||
|
|
||
|
;; (provide 'nregex)
|