;;; Guile Emacs Lisp ;;; Copyright (C) 2009, 2010, 2013 Free Software Foundation, Inc. ;;; ;;; This library is free software; you can redistribute it and/or ;;; modify it under the terms of the GNU Lesser General Public ;;; License as published by the Free Software Foundation; either ;;; version 3 of the License, or (at your option) any later version. ;;; ;;; This library is distributed in the hope that it will be useful, ;;; but WITHOUT ANY WARRANTY; without even the implied warranty of ;;; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU ;;; Lesser General Public License for more details. ;;; ;;; You should have received a copy of the GNU Lesser General Public ;;; License along with this library; if not, write to the Free Software ;;; Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA ;;; Code: (define-module (language elisp lexer) #:use-module (ice-9 regex) #:use-module (language elisp runtime) #:export (get-lexer get-lexer/1)) ;;; This is the lexical analyzer for the elisp reader. It is ;;; hand-written instead of using some generator. I think this is the ;;; best solution because of all that fancy escape sequence handling and ;;; the like. ;;; ;;; Characters are handled internally as integers representing their ;;; code value. This is necessary because elisp allows a lot of fancy ;;; modifiers that set certain high-range bits and the resulting values ;;; would not fit into a real Scheme character range. Additionally, ;;; elisp wants characters as integers, so we just do the right thing... ;;; ;;; TODO: #@count comments ;;; Report an error from the lexer (that is, invalid input given). (define (lexer-error port msg . args) (apply error msg args)) ;;; In a character, set a given bit. This is just some bit-wise or'ing ;;; on the characters integer code and converting back to character. (define (set-char-bit chr bit) (logior chr (ash 1 bit))) ;;; Check if a character equals some other. This is just like char=? ;;; except that the tested one could be EOF in which case it simply ;;; isn't equal. (define (is-char? tested should-be) (and (not (eof-object? tested)) (char=? tested should-be))) ;;; For a character (as integer code), find the real character it ;;; represents or #\nul if out of range. This is used to work with ;;; Scheme character functions like char-numeric?. (define (real-character chr) (if (< chr 256) (integer->char chr) #\nul)) ;;; Return the control modified version of a character. This is not ;;; just setting a modifier bit, because ASCII conrol characters must be ;;; handled as such, and in elisp C-? is the delete character for ;;; historical reasons. Otherwise, we set bit 26. (define (add-control chr) (let ((real (real-character chr))) (if (char-alphabetic? real) (- (char->integer (char-upcase real)) (char->integer #\@)) (case real ((#\?) 127) ((#\@) 0) (else (set-char-bit chr 26)))))) ;;; Parse a charcode given in some base, basically octal or hexadecimal ;;; are needed. A requested number of digits can be given (#f means it ;;; does not matter and arbitrary many are allowed), and additionally ;;; early return allowed (if fewer valid digits are found). These ;;; options are all we need to handle the \u, \U, \x and \ddd (octal ;;; digits) escape sequences. (define (charcode-escape port base digits early-return) (let iterate ((result 0) (procdigs 0)) (if (and digits (>= procdigs digits)) result (let* ((cur (read-char port)) (value (cond ((char-numeric? cur) (- (char->integer cur) (char->integer #\0))) ((char-alphabetic? cur) (let ((code (- (char->integer (char-upcase cur)) (char->integer #\A)))) (if (< code 0) #f (+ code 10)))) (else #f))) (valid (and value (< value base)))) (if (not valid) (if (or (not digits) early-return) (begin (unread-char cur port) result) (lexer-error port "invalid digit in escape-code" base cur)) (iterate (+ (* result base) value) (1+ procdigs))))))) ;;; Read a character and process escape-sequences when necessary. The ;;; special in-string argument defines if this character is part of a ;;; string literal or a single character literal, the difference being ;;; that in strings the meta modifier sets bit 7, while it is bit 27 for ;;; characters. (define basic-escape-codes '((#\a . 7) (#\b . 8) (#\t . 9) (#\n . 10) (#\v . 11) (#\f . 12) (#\r . 13) (#\e . 27) (#\s . 32) (#\d . 127))) (define (get-character port in-string) (let ((meta-bits `((#\A . 22) (#\s . 23) (#\H . 24) (#\S . 25) (#\M . ,(if in-string 7 27)))) (cur (read-char port))) (if (char=? cur #\\) ;; Handle an escape-sequence. (let* ((escaped (read-char port)) (esc-code (assq-ref basic-escape-codes escaped)) (meta (assq-ref meta-bits escaped))) (cond ;; Meta-check must be before esc-code check because \s- must ;; be recognized as the super-meta modifier if a - follows. ;; If not, it will be caught as \s -> space escape code. ((and meta (is-char? (peek-char port) #\-)) (if (not (char=? (read-char port) #\-)) (error "expected - after control sequence")) (set-char-bit (get-character port in-string) meta)) ;; One of the basic control character escape names? (esc-code esc-code) ;; Handle \ddd octal code if it is one. ((and (char>=? escaped #\0) (charinteger escaped)))))) ;; No escape-sequence, just the literal character. But remember ;; to get the code instead! (char->integer cur)))) ;;; Read a symbol or number from a port until something follows that ;;; marks the start of a new token (like whitespace or parentheses). ;;; The data read is returned as a string for further conversion to the ;;; correct type, but we also return what this is ;;; (integer/float/symbol). If any escaped character is found, it must ;;; be a symbol. Otherwise we at the end check the result-string ;;; against regular expressions to determine if it is possibly an ;;; integer or a float. (define integer-regex (make-regexp "^[+-]?[0-9]+\\.?$")) (define float-regex (make-regexp "^[+-]?([0-9]+\\.?[0-9]*|[0-9]*\\.?[0-9]+)(e[+-]?[0-9]+)?$")) ;;; A dot is also allowed literally, only a single dort alone is parsed ;;; as the 'dot' terminal for dotted lists. (define no-escape-punctuation (string->char-set "-+=*/_~!@$%^&:<>{}?.")) (define (get-symbol-or-number port) (let iterate ((result-chars '()) (had-escape #f)) (let* ((c (read-char port)) (finish (lambda () (let ((result (list->string (reverse result-chars)))) (values (cond ((and (not had-escape) (regexp-exec integer-regex result)) 'integer) ((and (not had-escape) (regexp-exec float-regex result)) 'float) (else 'symbol)) result)))) (need-no-escape? (lambda (c) (or (char-numeric? c) (char-alphabetic? c) (char-set-contains? no-escape-punctuation c))))) (cond ((eof-object? c) (finish)) ((need-no-escape? c) (iterate (cons c result-chars) had-escape)) ((char=? c #\\) (iterate (cons (read-char port) result-chars) #t)) (else (unread-char c port) (finish)))))) ;;; Parse a circular structure marker without the leading # (which was ;;; already read and recognized), that is, a number as identifier and ;;; then either = or #. (define (get-circular-marker port) (call-with-values (lambda () (let iterate ((result 0)) (let ((cur (read-char port))) (if (char-numeric? cur) (let ((val (- (char->integer cur) (char->integer #\0)))) (iterate (+ (* result 10) val))) (values result cur))))) (lambda (id type) (case type ((#\#) `(circular-ref . ,id)) ((#\=) `(circular-def . ,id)) (else (lexer-error port "invalid circular marker character" type)))))) ;;; Main lexer routine, which is given a port and does look for the next ;;; token. (define lexical-binding-regexp (make-regexp "-\\*-(|.*;)[ \t]*lexical-binding:[ \t]*([^;]*[^ \t;]).*-\\*-")) (define (lex port) (define (lexical-binding-value string) (and=> (regexp-exec lexical-binding-regexp string) (lambda (match) (not (member (match:substring match 2) '("nil" "()")))))) (let* ((return (let ((file (if (file-port? port) (port-filename port) #f)) (line (1+ (port-line port))) (column (1+ (port-column port)))) (lambda (token value) (let ((obj (cons token value))) (set-source-property! obj 'filename file) (set-source-property! obj 'line line) (set-source-property! obj 'column column) obj)))) ;; Read afterwards so the source-properties are correct above ;; and actually point to the very character to be read. (c (read-char port))) (cond ;; End of input must be specially marked to the parser. ((eof-object? c) (return 'eof c)) ;; Whitespace, just skip it. ((char-whitespace? c) (lex port)) ;; The dot is only the one for dotted lists if followed by ;; whitespace. Otherwise it is considered part of a number of ;; symbol. ((and (char=? c #\.) (char-whitespace? (peek-char port))) (return 'dot #f)) ;; Continue checking for literal character values. (else (case c ;; A line comment, skip until end-of-line is found. ((#\;) (if (= (port-line port) 0) (let iterate ((chars '())) (let ((cur (read-char port))) (if (or (eof-object? cur) (char=? cur #\newline)) (let ((string (list->string (reverse chars)))) (return 'set-lexical-binding-mode! (lexical-binding-value string))) (iterate (cons cur chars))))) (let iterate () (let ((cur (read-char port))) (if (or (eof-object? cur) (char=? cur #\newline)) (lex port) (iterate)))))) ;; A character literal. ((#\?) (return 'character (get-character port #f))) ;; A literal string. This is mainly a sequence of characters ;; just as in the character literals, the only difference is ;; that escaped newline and space are to be completely ignored ;; and that meta-escapes set bit 7 rather than bit 27. ((#\") (let iterate ((result-chars '())) (let ((cur (read-char port))) (case cur ((#\") (return 'string (make-lisp-string (list->string (reverse result-chars))))) ((#\\) (let ((escaped (read-char port))) (case escaped ((#\newline #\space) (iterate result-chars)) (else (unread-char escaped port) (unread-char cur port) (iterate (cons (integer->char (get-character port #t)) result-chars)))))) (else (iterate (cons cur result-chars))))))) ((#\#) (let ((c (read-char port))) (case c ((#\0 #\1 #\2 #\3 #\4 #\5 #\6 #\7 #\8 #\9) (unread-char c port) (let ((mark (get-circular-marker port))) (return (car mark) (cdr mark)))) ((#\') (return 'function #f)) ((#\:) (call-with-values (lambda () (get-symbol-or-number port)) (lambda (type str) (return 'symbol (make-symbol str)))))))) ;; Parentheses and other special-meaning single characters. ((#\() (return 'paren-open #f)) ((#\)) (return 'paren-close #f)) ((#\[) (return 'square-open #f)) ((#\]) (return 'square-close #f)) ((#\') (return 'quote #f)) ((#\`) (return 'backquote #f)) ;; Unquote and unquote-splicing. ((#\,) (if (is-char? (peek-char port) #\@) (if (not (char=? (read-char port) #\@)) (error "expected @ in unquote-splicing") (return 'unquote-splicing #f)) (return 'unquote #f))) ;; Remaining are numbers and symbols. Process input until next ;; whitespace is found, and see if it looks like a number ;; (float/integer) or symbol and return accordingly. (else (unread-char c port) (call-with-values (lambda () (get-symbol-or-number port)) (lambda (type str) (case type ((symbol) (cond ((equal? str "nil") (return 'symbol #nil)) ((equal? str "t") (return 'symbol #t)) (else ;; str could be empty if the first character is already ;; something not allowed in a symbol (and not escaped)! ;; Take care about that, it is an error because that ;; character should have been handled elsewhere or is ;; invalid in the input. (if (zero? (string-length str)) (begin ;; Take it out so the REPL might not get into an ;; infinite loop with further reading attempts. (read-char port) (error "invalid character in input" c)) (return 'symbol (string->symbol str)))))) ((integer) ;; In elisp, something like "1." is an integer, while ;; string->number returns an inexact real. Thus we need ;; a conversion here, but it should always result in an ;; integer! (return 'integer (let ((num (inexact->exact (string->number str)))) (if (not (integer? num)) (error "expected integer" str num)) num))) ((float) (return 'float (let ((num (string->number str))) (if (exact? num) (error "expected inexact float" str num)) num))) (else (error "wrong number/symbol type" type))))))))))) ;;; Build a lexer thunk for a port. This is the exported routine which ;;; can be used to create a lexer for the parser to use. (define (get-lexer port) (lambda () (lex port))) ;;; Build a special lexer that will only read enough for one expression ;;; and then always return end-of-input. If we find one of the quotation ;;; stuff, one more expression is needed in any case. (define (get-lexer/1 port) (let ((lex (get-lexer port)) (finished #f) (paren-level 0)) (lambda () (if finished (cons 'eof ((@ (ice-9 binary-ports) eof-object))) (let ((next (lex)) (quotation #f)) (case (car next) ((paren-open square-open) (set! paren-level (1+ paren-level))) ((paren-close square-close) (set! paren-level (1- paren-level))) ((quote backquote unquote unquote-splicing circular-def) (set! quotation #t))) (if (and (not quotation) (<= paren-level 0)) (set! finished #t)) next)))))