;; SAL parser -- replaces original pattern-directed parser with ;; a recursive descent one ;; ;; Parse functions either parse correctly and return ;; compiled code as a lisp expression (which could be nil) ;; or else they call parse-error, which does not return ;; (instead, parse-error forces a return from parse) ;; In the original SAL parser, triples were returned ;; including the remainder if any of the tokens to be ;; parsed. In this parser, tokens are on the list ;; *sal-tokens*, and whatever remains on the list is ;; the list of unparsed tokens. ;; scanning delimiters. (setfn nreverse reverse) (defconstant +quote+ #\") ; "..." string (defconstant +kwote+ #\') ; '...' kwoted expr (defconstant +comma+ #\,) ; positional arg delimiter (defconstant +pound+ #\#) ; for bools etc (defconstant +semic+ #\;) ; comment char (defconstant +lbrace+ #\{) ; {} list notation (defconstant +rbrace+ #\}) (defconstant +lbrack+ #\[) ; unused for now (defconstant +rbrack+ #\]) (defconstant +lparen+ #\() ; () expr and arg grouping (defconstant +rparen+ #\)) ;; these are defined so that SAL programs can name these symbols ;; note that quote(>) doesn't work, so you need quote(symbol:greater) (setf symbol:greater '>) (setf symbol:less '<) (setf symbol:greater-equal '>=) (setf symbol:less-equal '<=) (setf symbol:equal '=) (setf symbol:not '!) (setf symbol:not-equal '/=) (defparameter +whites+ (list #\space #\tab #\newline (code-char 13))) (defparameter +kwstyle+ (list :suffix #\:)) ; let's try dylan (defparameter +operators+ ;; each op is: (

) '((:+ "+" sum) (:- "-" diff) (:* "*" mult) (:/ "/" /) (:% "%" rem) (:^ "^" expt) (:= "=" eql) ; equality and assigment (:!= "!=" not-eql) (:< "<" <) (:> ">" >) (:<= "<=" <=) ; leq and assignment minimization (:>= ">=" >=) ; geq and assignment maximization (:~= "~=" equal) ; general equality (:+= "+=" +=) ; assignment increment-and-store (:-= "-=" -=) ; assignment increment-and-store (:*= "*=" *=) ; assignment multiply-and-store (:/= "/=" /=) ; assignment multiply-and-store (:&= "&=" &=) ; assigment list collecting (:@= "@=" @=) ; assigment list prepending (:^= "^=" ^=) ; assigment list appending (:! "!" not) (:& "&" and) (:\| "|" or) (:~ "~" sal-stretch) (:~~ "~~" sal-stretch-abs) (:@ "@" sal-at) (:@@ "@@" sal-at-abs) )) (setf *sal-local-variables* nil) ;; used to avoid warning about variable ;; names when the variable has been declared as a local (defparameter *sal-operators* '(:+ :- :* :/ :% :^ := :!= :< :> :<= :>= :~= :+= :*= :&= :@= :^= :! :& :\| :~ :~~ :@ :@@)) (defparameter +delimiters+ '((:lp #\() (:rp #\)) (:lc #\{) ; left curly (:rc #\}) (:lb #\[) (:rb #\]) (:co #\,) (:kw #\') ; kwote (nil #\") ; not token ; (nil #\#) (nil #\;) )) (setf *reserved-words* '((::+ ":+") (::- ":-") (::* ":*") (::/ ":/") (::= ":=") (::!= ":!=") (::< ":<") (::> ":>") (::<= ":<=") (::>= ":>=") (::~= ":~=") (::! ":!") (::& ":&") (::\| ":|") (:IF "if") (:THEN "then") (:ELSE "else") (:WHEN "when") (:UNLESS "unless") (:SET "set") (:= "=") (:+= "+=") (:*= "*=") (:&= "&=") (:@= "@=") (:^= "^=") (:<= "<=") (:>= ">=") (:PRINT "print") (:LOOP "loop") (:RUN "run") (:REPEAT "repeat") (:FOR "for") (:FROM "from") (:IN "in") (:BELOW "below") (:TO "to") (:ABOVE "above") (:DOWNTO "downto") (:BY "by") (:OVER "over") (:WHILE "while") (:UNTIL "until") (:FINALLY "finally") (:RETURN "return") (:WAIT "wait") (:BEGIN "begin") (:WITH "with") (:END "end") (:VARIABLE "variable") (:FUNCTION "function") (:PROCESS "process") (:CHDIR "chdir") (:DEFINE "define") (:LOAD "load") (:PLAY "play") (:EXEC "exec") (:exit "exit") (:DISPLAY "display") (:~ "~") (:~~ "~~") (:@ ":@") (:@@ ":@@"))) (setf *sal-fn-name* nil) (defun make-sal-error (&key type text (line nil) start) ; (error 'make-sal-error-was-called-break) (list 'sal-error type text line start)) (setfn sal-error-type cadr) (setfn sal-error-text caddr) (setfn sal-error-line cadddr) (defun sal-error-start (x) (cadddr (cdr x))) (defun is-sal-error (x) (and x (eq (car x) 'sal-error))) (defun sal-tokens-error-start (start) (cond (start start) (*sal-tokens* (token-start (car *sal-tokens*))) (t (length *sal-input-text*)))) (defmacro errexit (message &optional start) `(parse-error (make-sal-error :type "parse" :line *sal-input-text* :text ,message :start ,(sal-tokens-error-start start)))) (defmacro sal-warning (message &optional start) `(pperror (make-sal-error :type "parse" :line *sal-input-text* :text ,message :start ,(sal-tokens-error-start start)) "warning")) (setf *pos-to-line-source* nil) (setf *pos-to-line-pos* nil) (setf *pos-to-line-line* nil) (defun pos-to-line (pos source) ;; this is really inefficient to search every line from ;; the beginning, so cache results and search forward ;; from there if possible (let ((i 0) (line-no 1)) ;; assume no cache ;; see if we can use the cache (cond ((and (eq source *pos-to-line-source*) *pos-to-line-pos* *pos-to-line-line* (>= pos *pos-to-line-pos*)) (setf i *pos-to-line-pos*) (setf line-no *pos-to-line-line*))) ;; count newlines up to pos (while (< i pos) (if (char= (char source i) #\newline) (incf line-no)) (setf i (1+ i))) ;; save results in cache (setf *pos-to-line-source* source *pos-to-line-pos* pos *pos-to-line-line* line-no) ;; return the line number at pos in source line-no)) ;; makes a string of n spaces, empty string if n <= 0 (defun make-spaces (n) (cond ((> n 16) (let* ((half (/ n 2)) (s (make-spaces half))) (strcat s s (make-spaces (- n half half))))) (t (subseq " " 0 (max n 0))))) (defun pperror (x &optional (msg-type "error")) (let* ((source (sal-error-line x)) (llen (length source)) line-no beg end) ; (display "pperror" x (strcat "|" (sal-error-line x) "|")) ;; isolate line containing error (setf beg (sal-error-start x)) (setf beg (min beg (1- llen))) (do ((i beg (- i 1)) (n nil)) ; n gets set when we find a newline ((or (< i 0) n) (setq beg (or n 0))) (if (char= (char source i) #\newline) (setq n (+ i 1)))) (do ((i (sal-error-start x) (+ i 1)) (n nil)) ((or (>= i llen) n) (setq end (or n llen))) (if (char= (char source i) #\newline) (setq n i))) (setf line-no (pos-to-line beg source)) ; (display "pperror" beg end (sal-error-start x)) ;; print the error. include the specfic line of input containing ;; the error as well as a line below it marking the error position ;; with an arrow: ^ (let* ((pos (- (sal-error-start x) beg)) (line (if (and (= beg 0) (= end llen)) source (subseq source beg end))) (mark (make-spaces pos))) (format t "~%>>> ~A ~A: ~A.~%>>> in ~A, line ~A, col ~A.~%~%~A~%~A^~%" (sal-error-type x) msg-type (sal-error-text x) *sal-input-file-name* line-no (1+ pos) line mark) ; (format t "~%>>> ~A error in \"~A\", line ~A, col ~A: ~A.~%~%~A~%~A^~%" ; (sal-error-type x) *sal-input-file-name* line-no pos ; (sal-error-text x) line mark) x))) ;;; ;;; the lexer. right now it assumes input string is complete and ready ;;; to be processed as a valid expression. ;;; (defun advance-white (str white start end) ;; skip "white" chars, where white can be a char, list of chars ;; or predicate test (do ((i start ) (p nil)) ((or p (if (< start end) (not (< -1 i end)) (not (> i end -1)))) (or p end)) (cond ((consp white) (unless (member (char str i) white :test #'char=) (setq p i))) ((characterp white) (unless (char= (char str i) white) (setq p i))) ((functionp white) (unless (funcall white (char str i)) (setq p i)))) (if (< start end) (incf i) (decf i)))) (defun search-delim (str delim start end) ;; find position of "delim" chars, where delim can be ;; a char, list of chars or predicate test (do ((i start (+ i 1)) (p nil)) ((or (not (< i end)) p) (or p end)) (cond ((consp delim) (if (member (char str i) delim :test #'char=) (setq p i))) ((characterp delim) (if (char= (char str i) delim) (setq p i))) ((functionp delim) (if (funcall delim (char str i)) (setq p i)))))) ;; UNBALANCED-INPUT AND TOKENIZE HAVE BEEN REWRITTEN, SEE BELOW. THIS ONE IS ;; OLD AND JUST KEPT HERE FOR REFERENCE #| (defun unbalanced-input (errf line toks par bra brk kwo) ;; search input for the starting position of some unbalanced ;; delimiter, toks is reversed list of tokens with something ;; unbalanced (let (char text targ othr levl pos) (cond ((> par 0) (setq char #\( targ ':lp othr ':rp levl par)) ((< par 0) (setq char #\) targ ':rp othr ':lp levl 0)) ((> bra 0) (setq char #\{ targ ':lc othr ':rc levl bra)) ((< bra 0) (setq char #\} targ ':rc othr ':lc levl 0)) ((> brk 0) (setq char #\[ targ ':ls othr ':rs levl brk)) ((< brk 0) (setq char #\] targ ':rs othr ':ls levl 0)) ((> kwo 0) (setq char #\' targ ':kw othr ':kw levl kwo))) (setq text (format nil "Unmatched '~A'" char)) ;; search for start of error in token list (do ((n levl) (tail toks (cdr tail))) ((or (null tail) pos) (or pos (error (format nil "Shouldn't! can't find op ~A in ~A." targ (reverse toks))))) (if (eql (token-type (car tail)) targ) (if (= n levl) (setq pos (token-start (car tail))) (decf n)) (if (eql (token-type (car tail)) othr) (incf n)))) (errexit text pos))) (defun tokenize (str reserved error-fn) ;&key (start 0) (end (length str)) ; (white-space +whites+) (delimiters +delimiters+) ; (operators +operators+) (null-ok t) ; (keyword-style +kwstyle+) (reserved nil) ; (error-fn nil) ; &allow-other-keys) ;; return zero or more tokens or a sal-error (let ((toks (list t)) (start 0) (end (length str)) (all-delimiters +whites+) (errf (or error-fn (lambda (x) (pperror x) (return-from tokenize x))))) (dolist (x +delimiters+) (push (cadr x) all-delimiters)) (do ((beg start) (pos nil) (all all-delimiters) (par 0) (bra 0) (brk 0) (kwo 0) (tok nil) (tail toks)) ((not (< beg end)) ;; since input is complete check parens levels. (if (= 0 par bra brk kwo) (if (null (cdr toks)) (list) (cdr toks)) (unbalanced-input errf str (reverse (cdr toks)) par bra brk kwo))) (setq beg (advance-white str +whites+ beg end)) (setf tok (read-delimited str :start beg :end end :white +whites+ :delimit all :skip-initial-white nil :errorf errf)) ;; multiple values are returned, so split them here: (setf pos (second tok)) ; pos is the end of the token (!) (setf tok (first tok)) ;; tok now string, char (delimiter), :eof or token since input ;; is complete keep track of balancing delims (cond ((eql tok +lbrace+) (incf bra)) ((eql tok +rbrace+) (decf bra)) ((eql tok +lparen+) (incf par)) ((eql tok +rparen+) (decf par)) ((eql tok +lbrack+) (incf brk)) ((eql tok +rbrack+) (decf brk)) ((eql tok +kwote+) (setq kwo (mod (+ kwo 1) 2)))) (cond ((eql tok ':eof) (setq beg end)) (t ;; may have to skip over comments to reach token, so ;; token beginning is computed by backing up from current ;; position (returned by read-delimited) by string length (setf beg (if (stringp tok) (- pos (length tok)) (1- pos))) (setq tok (classify-token tok beg str errf +delimiters+ +operators+ +kwstyle+ reserved)) ;(display "classify-token-result" tok) (setf (cdr tail) (list tok )) (setf tail (cdr tail)) (setq beg pos)))))) |# ;; old tokenize (above) counted delimiters to check for balance, ;; but that does not catch constructions like ({)}. I think ;; we could just leave this up to the parser, but this rewrite ;; uses a stack to check balanced parens, braces, quotes, etc. ;; The checking establishes at least some minimal global properties ;; of the input before evaluating anything, which might be good ;; even though it's doing some extra work. In fact, using a ;; stack rather than counts is doing even more work, but the ;; problem with counters is that some very misleading or just ;; plain wrong error messages got generated. ;; ;; these five delimiter- functions do checks on balanced parens, ;; braces, and brackets, leaving delimiter-mismatch set to bad ;; token if there is a mismatch (defun delimiter-init () (setf delimiter-stack nil) (setf delimiter-mismatch nil)) (defun delimiter-match (tok what) (cond ((eql (token-string (first delimiter-stack)) what) (pop delimiter-stack)) ((null delimiter-mismatch) ;(display "delimiter-mismatch" tok) (setf delimiter-mismatch tok)))) (defun delimiter-check (tok) (let ((c (token-string tok))) (cond ((member c '(#\( #\{ #\[)) (push tok delimiter-stack)) ((eql c +rbrace+) (delimiter-match tok +lbrace+)) ((eql c +rparen+) (delimiter-match tok +lparen+)) ((eql c +rbrack+) (delimiter-match tok +lbrack+))))) (defun delimiter-error (tok) (errexit (format nil "Unmatched '~A'" (token-string tok)) (token-start tok))) (defun delimiter-finish () (if delimiter-mismatch (delimiter-error delimiter-mismatch)) (if delimiter-stack (delimiter-error (car delimiter-stack)))) (defun tokenize (str reserved error-fn) ;; return zero or more tokens or a sal-error (let ((toks (list t)) (start 0) (end (length str)) (all-delimiters +whites+) (errf (or error-fn (lambda (x) (pperror x) (return-from tokenize x))))) (dolist (x +delimiters+) (push (cadr x) all-delimiters)) (delimiter-init) (do ((beg start) (pos nil) (all all-delimiters) (tok nil) (tail toks)) ((not (< beg end)) ;; since input is complete check parens levels. (delimiter-finish) (if (null (cdr toks)) nil (cdr toks))) (setq beg (advance-white str +whites+ beg end)) (setf tok (read-delimited str :start beg :end end :white +whites+ :delimit all :skip-initial-white nil :errorf errf)) ;; multiple values are returned, so split them here: (setf pos (second tok)) ; pos is the end of the token (!) (setf tok (first tok)) (cond ((eql tok ':eof) (setq beg end)) (t ;; may have to skip over comments to reach token, so ;; token beginning is computed by backing up from current ;; position (returned by read-delimited) by string length (setf beg (if (stringp tok) (- pos (length tok)) (1- pos))) (setq tok (classify-token tok beg str errf +delimiters+ +operators+ +kwstyle+ reserved)) (delimiter-check tok) ;(display "classify-token-result" tok) (setf (cdr tail) (list tok )) (setf tail (cdr tail)) (setq beg pos)))))) (defun read-delimited (input &key (start 0) end (null-ok t) (delimit +delims+) ; includes whites... (white +whites+) (skip-initial-white t) (errorf #'pperror)) ;; read a substring from input, optionally skipping any white chars ;; first. reading a comment delim equals end-of-line, input delim ;; reads whole input, pound reads next token. call errf if error ;(FORMAT T "~%READ-DELIMITED: ~S :START ~S :END ~S" input start end) (let ((len (or end (length input)))) (while t ;; loop over comment lines (when skip-initial-white (setq start (advance-white input white start len))) (if (< start len) (let ((char (char input start))) (setq end (search-delim input delimit start len)) (if (equal start end) ; have a delimiter (cond ((char= char +semic+) ;; comment skips to next line and trys again... (while (and (< start len) (char/= (char input start) #\newline)) (incf start)) (cond ((< start len) ;; advance past comment and iterate (incf start) (setf skip-initial-white t)) (null-ok (return (list ':eof end))) (t (errexit "Unexpected end of input")))) ; ((char= char +pound+) ; ;; read # dispatch ; (read-hash input delimit start len errorf)) ((char= char +quote+) ;; input delim reads whole input (return (sal:read-string input delimit start len errorf))) ((char= char +kwote+) (errexit "Illegal delimiter" start)) (t ;; all other delimiters are tokens in and of themselves (return (list char (+ start 1))))) ; else part of (equal start end), so we have token before delimiter (return (list (subseq input start end) end)))) ; else part of (< start len)... (if null-ok (return (list ':eof end)) (errexit "Unexpected end of input" start)))))) (defparameter hash-readers '(( #\t sal:read-bool) ( #\f sal:read-bool) ( #\? read-iftok) )) (defun read-hash (str delims pos len errf) (let ((e (+ pos 1))) (if (< e len) (let ((a (assoc (char str e) hash-readers))) (if (not a) (errexit "Illegal # character" e) (funcall (cadr a) str delims e len errf))) (errexit "Missing # character" pos)))) (defun read-iftok (str delims pos len errf) str delims len errf (list (make-token :type ':? :string "#?" :lisp 'if :start (- pos 1)) (+ pos 1))) ; (sal:read-string str start len) (defun sal:read-bool (str delims pos len errf) delims len errf (let ((end (search-delim str delims pos len))) (unless (= end (+ pos 1)) (errexit "Illegal # expression" (- pos 1))) (list (let ((t? (char= (char str pos) #\t) )) (make-token :type ':bool :string (if t? "#t" "#f") :lisp t? :start (- pos 1))) (+ pos 1)))) (defun sal:read-string (str delims pos len errf) (let* ((i (1+ pos)) ; i is index into string; start after open quote c c2; c is the character at str[i] (string (make-string-output-stream))) ;; read string, processing escaped characters ;; write the chars to string until end quote is found ;; then retrieve the string. quotes are not included in result token ;; in the loop, i is the next character location to examine (while (and (< i len) (not (char= (setf c (char str i)) +quote+))) (if (char= c #\\) ;; escape character, does another character follow this? (cond ((< (1+ i) len) (incf i) ;; yes, set i so we'll get the escaped char (setf c2 (char str i)) (setf c (assoc c2 `((#\n . #\newline) (#\t . #\tab) (#\r . ,(char "\r" 0)) (#\f . ,(char "\f" 0))))) (setf c (if c (cdr c) c2))) ;; use c2 if c wasn't listed (t ;; no, we've hit the end of input too early (errexit "Unmatched \"" i)))) ;; we're good to take this character and move on to the next one (write-char c string) (incf i)) ;; done with loop, so either we're out of string or we found end quote (if (>= i len) (errexit "Unmatched \"" i)) ;; must have found the quote (setf string (get-output-stream-string string)) (list (make-token :type :string :start pos :string string :lisp string) (1+ i)))) ;;; ;;; tokens ;;; (defun make-token (&key (type nil) (string "") start (info nil) lisp) (list :token type string start info lisp)) (setfn token-type cadr) (setfn token-string caddr) (defun token-start (x) (cadddr x)) (defun token-info (token) (car (cddddr token))) (defun token-lisp (token) (cadr (cddddr token))) (defmacro set-token-type (tok val) `(setf (car (cdr ,tok)) ,val)) (defmacro set-token-lisp (tok val) `(setf (car (cdr (cddddr ,tok))) ,val)) (defun tokenp (tok) (and (consp tok) (eq (car tok) :token))) (defun token=? (tok op) (if (tokenp tok) (equal (token-type tok) op) (eql tok op))) (defmethod token-print (obj stream) (let ((*print-case* ':downcase)) (format stream "#<~s ~s>" (token-type obj) (token-string obj)))) (defun parse-token () (prog1 (car *sal-tokens*) (setf *sal-tokens* (cdr *sal-tokens*)))) ;;; ;;; token classification. types not disjoint! ;;; (defun classify-token (str pos input errf delims ops kstyle res) (let ((tok nil)) (cond ((characterp str) ;; normalize char delimiter tokens (setq tok (delimiter-token? str pos input errf delims))) ((stringp str) (setq tok (or (number-token? str pos input errf) (operator-token? str pos input errf ops) (keyword-token? str pos input errf kstyle) (class-token? str pos input errf res) (reserved-token? str pos input errf res) (symbol-token? str pos input errf) )) (unless tok (errexit "Not an expression or symbol" pos))) (t (setq tok str))) tok)) (defun delimiter-token? (str pos input errf delims) (let ((typ (member str delims :test (lambda (a b) (char= a (cadr b)))))) ;; member returns remainder of the list ;(display "delimiter-token?" str delims typ) (if (and typ (car typ) (caar typ)) (make-token :type (caar typ) :string str :start pos) (+ (break) (errexit "Shouldn't: non-token delimiter" pos))))) (defun string-to-number (s) (read (make-string-input-stream s))) (defun number-token? (str pos input errf) errf input (do ((i 0 (+ i 1)) (len (length str)) (c nil) (dot 0) (typ ':int) (sig 0) (sla 0) (dig 0) (non nil)) ((or (not (< i len)) non) (if non nil (if (> dig 0) (make-token :type typ :string str :start pos :lisp (string-to-number str)) nil))) (setq c (char str i)) (cond ((member c '(#\+ #\-)) (if (> i 0) (setq non t) (incf sig))) ((char= c #\.) (if (> dot 0) (setq non t) (if (> sla 0) (setq non t) (incf dot)))) ; xlisp does not have ratios ; ((char= c #\/) ; (setq typ ':ratio) ; (if (> sla 0) (setq non t) ; (if (= dig 0) (setq non t) ; (if (> dot 0) (setq non t) ; (if (= i (1- len)) (setq non t) ; (incf sla)))))) ((digit-char-p c) (incf dig) (if (> dot 0) (setq typ ':float))) (t (setq non t))))) #|| (number-token? "" 0 "" #'pperror) (number-token? " " 0 "" #'pperror) (number-token? "a" 0 "" #'pperror) (number-token? "1" 0 "" #'pperror) (number-token? "+" 0 "" #'pperror) (number-token? "-1/2" 0 "" #'pperror) (number-token? "1." 0 "" #'pperror) (number-token? "1.." 0 "" #'pperror) (number-token? ".1." 0 "" #'pperror) (number-token? ".1" 0 "" #'pperror) (number-token? "-0.1" 0 "" #'pperror) (number-token? "1/2" 0 "" #'pperror) (number-token? "1//2" 0 "" #'pperror) (number-token? "/12" 0 "" #'pperror) (number-token? "12/" 0 "" #'pperror) (number-token? "12/1" 0 "" #'pperror) (number-token? "12./1" 0 "" #'pperror) (number-token? "12/.1" 0 "" #'pperror) ||# (defun operator-token? (str pos input errf ops) ;; tok can be string or char (let ((typ (member str ops :test (lambda (a b) (equal a (cadr b)))))) (cond (typ (setf typ (car typ)) ;; member returns remainder of list (make-token :type (car typ) :string str :start pos :lisp (or (third typ) (read-from-string str))))))) (defun str-to-keyword (str) (intern (strcat ":" (string-upcase str)))) (defun keyword-token? (tok pos input errf style) (let* ((tlen (length tok)) (keys (cdr style)) (klen (length keys))) (cond ((not (< klen tlen)) nil) ((eql (car style) ':prefix) (do ((i 0 (+ i 1)) (x nil)) ((or (not (< i klen)) x) (if (not x) (let ((sym (symbol-token? (subseq tok i) pos input errf ))) (cond (sym (set-token-type sym ':key) (set-token-lisp sym (str-to-keyword (token-string sym))) sym))) nil)) (unless (char= (char tok i) (nth i keys)) (setq x t)))) ((eql (car style) ':suffix) (do ((j (- tlen klen) (+ j 1)) (i 0 (+ i 1)) (x nil)) ((or (not (< i klen)) x) (if (not x) (let ((sym (symbol-token? (subseq tok 0 (- tlen klen)) pos input errf ))) (cond (sym (set-token-type sym ':key) (set-token-lisp sym (str-to-keyword (token-string sym))) sym))) nil)) (unless (char= (char tok j) (nth i keys)) (setq x t))))))) (setfn alpha-char-p both-case-p) (defun class-token? (str pos input errf res) res (let ((a (char str 0))) (if (char= a #\<) (let* ((l (length str)) (b (char str (- l 1)))) (if (char= b #\>) (let ((tok (symbol-token? (subseq str 1 (- l 1)) pos input errf))) ;; class token has <> removed! (if tok (progn (set-token-type tok ':class) tok) (errexit "Not a class identifer" pos))) (errexit "Not a class identifer" pos))) nil))) ; (keyword-token? ":asd" '(:prefix #\:)) ; (keyword-token? "asd" KSTYLE) ; (keyword-token? "asd:" KSTYLE) ; (keyword-token? "123:" KSTYLE) ; (keyword-token? ":foo" '(:prefix #\:)) ; (keyword-token? "foo=" '(:suffix #\=)) ; (keyword-token? "--foo" '(:prefix #\- #\-)) ; (keyword-token? ":123" '(:suffix #\:)) ; (keyword-token? "--asd" '(:prefix #\-)) ; ok since -asd is legal symbol (defun reserved-token? (str pos input errf reserved) errf input (let ((typ (member str reserved :test (lambda (a b) (equal a (cadr b)))))) (if typ (make-token :type (caar typ) :string str :start pos) nil))) (defun sal-string-to-symbol (str) (let ((sym (intern (string-upcase str))) sal-sym) (cond ((and sym ;; (it might be "nil") (setf sal-sym (get sym :sal-name))) sal-sym) (t sym)))) (putprop 'simrep 'sal-simrep :sal-name) (putprop 'seqrep 'sal-seqrep :sal-name) (defun contains-op-char (s) ;; assume most identifiers are very short, so we search ;; over identifier letters, not over operator characters ;; Minus (-) is so common, we don't complain about it. (dotimes (i (length s)) (if (string-search (subseq s i (1+ i)) "*/+=<>!%^&|") (return t)))) (defun test-for-suspicious-symbol (token) ;; assume token is of type :id (let ((sym (token-lisp token)) (str (token-string token)) (pos (token-start token))) (cond ((and sym ; nil is not suspicious, but it's not "boundp" (not (fboundp sym)) ; existing functions not suspicious (not (boundp sym)) ; existing globals not suspicious (not (member sym *sal-local-variables*)) (contains-op-char str)) ; suspicious if embedded operators (sal-warning (strcat "Identifier contains operator character(s).\n" " Perhaps you omitted spaces around an operator") pos))))) (defun symbol-token? (str pos input errf) ;; if a potential symbol is preceded by #, drop the # (if (and (> (length str) 1) (char= (char str 0) #\#)) ;; there are a couple of special cases: SAL defines #f and #? (cond ((equal str "#f") (return-from symbol-token? (make-token :type ':id :string str :start pos :lisp nil))) ((equal str "#?") (return-from symbol-token? (make-token :type ':id :string str :start pos :lisp 'if))) (t (setf str (subseq str 1))))) ;; let's insist on at least one letter for sanity's sake ;; exception: allow '-> because it is used in markov pattern specs (do ((i 0 (+ i 1)) ; i is index into string (bad "Not an expression or symbol") (chr nil) (ltr 0) ; ltr is count of alphabetic letters in string (dot nil) ; dot is index of "." (pkg nil) ; pkg is index if package name "xxx:" found (len (length str)) (err nil)) ;; loop ends when i is at end of string or when err is set ((or (not (< i len)) err) (if (or (> ltr 0) ; must be at least one letter, or (equal str "->")) ; symbol can be "->" (let ((info ()) sym) (if pkg (push (cons ':pkg pkg) info)) (if dot (push (cons ':slot dot) info)) ;(display "in symbol-token?" str) (setf sym (sal-string-to-symbol str)) (make-token :type ':id :string str :info info :start pos :lisp sym)) nil)) (setq chr (char str i)) (cond ((alpha-char-p chr) (incf ltr)) ; need to allow arbitrary lisp symbols ; ((member chr '(#\* #\+)) ;; special variable names can start/end ; (if (< 0 i (- len 2)) ;; with + or * ; (errexit bad pos))) ((char= chr #\/) ;; embedded / is not allowed (errexit bad pos)) ;((char= chr #\-) ;; hyphens are allowed anywhere in symbol ; (if (= ltr 0) ; (errexit errf input bad pos ) ; (setq ltr 0) ; )) ((char= chr #\:) ; allowable forms are :foo, foo:bar, :foo:bar (if (> i 0) ;; lisp keyword symbols ok (cond ((= ltr 0) (errexit bad pos)) ((not pkg) (setq pkg i)) (t (errexit errf input (format nil "Too many colons in ~s" str) pos)))) (setq ltr 0)) ((char= chr #\.) (if (or dot (= i 0) (= i (- len 1))) (errexit bad pos) (progn (setq dot i) (setq ltr 0))))))) ; (let ((i "foo")) (symbol-token? i 0 i #'pperror)) ; (let ((i "foo..bar")) (symbol-token? i 0 i #'pperror)) ; (let ((i ".bar")) (symbol-token? i 0 i #'pperror)) ; (let ((i "bar.")) (symbol-token? i 0 i #'pperror)) ; (let ((i "1...")) (symbol-token? i 0 i #'pperror)) ; (let ((i "a1..." )) (symbol-token? i 0 i #'pperror)) ; (let ((i "a{b")) (symbol-token? i 0 i #'pperror)) ; (let ((i "foo-bar")) (symbol-token? i 0 i #'pperror)) ; (let ((i "123-a")) (symbol-token? i 0 i #'pperror)) ; (let ((i "1a23-a")) (symbol-token? i 0 i #'pperror)) ; (let ((i "*foo*")) (symbol-token? i 0 i #'pperror)) ; (let ((i "+foo+")) (symbol-token? i 0 i #'pperror)) ; (let ((i "foo+bar")) (symbol-token? i 0 i #'pperror)) ; (let ((i "foo/bar")) (symbol-token? i 0 i #'pperror)) ; (let ((i ":bar")) (symbol-token? i 0 i #'pperror)) ; (let ((i "::bar")) (symbol-token? i 0 i #'pperror)) ; (let ((i "foo:bar")) (symbol-token? i 0 i #'pperror)) ; (let ((i "cl-user:bar")) (symbol-token? i 0 i #'pperror)) ; (let ((i "cl-user::bar")) (symbol-token? i 0 i #'pperror)) ; (tokenize "aaa + bbb \"asdasdd\" aaa(1,2,3)") ; (tokenize "aaa+bbb \"asdasdd\" aaa(1,2,3)") (setf *in-sal-parser* nil) ;; line number info for debugging (setf *sal-line-number-info* t) (setf *sal-line* 0) (defun add-line-info-to-expression (expr token) (let (line-no) (cond ((and token ;; null token means do not change expr *sal-line-number-info* ;; is this feature enabled? (stringp *sal-input-text*)) ;; first, get line number (setf line-no (pos-to-line (token-start token) *sal-input-text*)) `(prog2 (setf *sal-line* ,line-no) ,expr)) (t expr)))) ;; single statement is handled just like an expression (setfn add-line-info-to-stmt add-line-info-to-expression) ;; list of statements is simple to handle: prepend SETF (defun add-line-info-to-stmts (stmts token) (let (line-no) (cond ((and *sal-line-number-info* ;; is this feature enabled? (stringp *sal-input-text*)) (setf line-no (pos-to-line (token-start token) *sal-input-text*)) (cons `(setf *sal-line* ,line-no) stmts)) (t stmts)))) ;; PARSE-ERROR -- print error message, return from top-level ;; (defun parse-error (e) (unless (sal-error-line e) (setf (sal-error-line e) *sal-input*)) (pperror e) (return-from sal-parse (values nil e *sal-tokens*))) ;; SAL-PARSE -- parse string or token input, translate to Lisp ;; ;; If input is text, *sal-input-text* is set to the text and ;; read later (maybe) by ERREXIT. ;; If input is a token list, it is assumed these are leftovers ;; from tokenized text, so *sal-input-text* is already valid. ;; *Therfore*, do not call sal-parse with tokens unless ;; *sal-input-text* is set to the corresponding text. ;; (defun sal-parse (grammar pat input multiple-statements file) (progv '(*sal-input-file-name*) (list file) (let (rslt expr rest) ; ignore grammar and pat (just there for compatibility) ; parse input and return lisp expression (cond ((stringp input) (setf *sal-input-text* input) (setq input (tokenize input *reserved-words* #'parse-error)))) (setf *sal-input* input) ;; all input (setf *sal-tokens* input) ;; current input (cond ((null input) (values t nil nil)) ; e.g. comments compile to nil (t (setf rslt (or (maybe-parse-command) (maybe-parse-block) (maybe-parse-conditional) (maybe-parse-assignment) (maybe-parse-loop) (maybe-parse-exec) (maybe-parse-exit) (errexit "Syntax error"))) ;; note: there is a return-from parse in parse-error that ;; returns (values nil error ) (cond ((and *sal-tokens* (not multiple-statements)) (errexit "leftover tokens"))) ;((null rslt) ; (errexit "nothing to compile"))) (values t rslt *sal-tokens*)))))) ;; TOKEN-IS -- test if the type of next token matches expected type(s) ;; ;; type can be a list of possibilities or just a symbol ;; Usually, suspicious-id-warn is true by default, and any symbol ;; with embedded operator symbols, e.g. x+y results in a warning ;; that this is an odd variable name. But if the symbol is declared ;; as a local, a parameter, a function name, or a global variable, ;; then the warning is supressed. ;; (defun token-is (type &optional (suspicious-id-warn t)) (let ((token-type (if *sal-tokens* (token-type (car *sal-tokens*)) nil)) rslt) ; input can be list of possible types or just a type: (setf rslt (or (and (listp type) (member token-type type)) (and (symbolp type) (eq token-type type)))) ; test if symbol has embedded operator characters: (cond ((and rslt suspicious-id-warn (eq token-type :id)) (test-for-suspicious-symbol (car *sal-tokens*)))) rslt)) (defun maybe-parse-command () (if (token-is '(:define :load :chdir :variable :function ; :system :play :print :display)) (parse-command) (if (and (token-is '(:return)) *audacity-top-level-return-flag*) (parse-command)))) (defun parse-command () (cond ((token-is '(:define :variable :function)) (parse-declaration)) ((token-is :load) (parse-load)) ((token-is :chdir) (parse-chdir)) ((token-is :play) (parse-play)) ; ((token-is :system) ; (parse-system)) ((token-is :print) (parse-print-display :print 'sal-print)) ((token-is :display) (parse-print-display :display 'display)) ((and *audacity-top-level-return-flag* (token-is :return)) (parse-return)) ; ((token-is :output) ; (parse-output)) (t (errexit "Command not found")))) (defun parse-stmt () (cond ((token-is :begin) (parse-block)) ((token-is '(:if :when :unless)) (parse-conditional)) ((token-is :set) (parse-assignment)) ((token-is :loop) (parse-loop)) ((token-is :print) (parse-print-display :print 'sal-print)) ((token-is :display) (parse-print-display :display 'display)) ; ((token-is :output) ; (parse-output)) ((token-is :exec) (parse-exec)) ((token-is :exit) (parse-exit)) ((token-is :return) (parse-return)) ((token-is :load) (parse-load)) ((token-is :chdir) (parse-chdir)) ; ((token-is :system) ; (parse-system)) ((token-is :play) (parse-play)) (t (errexit "Command not found")))) ;; GET-PARM-NAMES -- given parms like (a b &key (x 1) (y 2)), ;; return list of parameters: (a b x y) (defun get-parm-names (parms) (let (rslt) (dolist (p parms) (cond ((symbolp p) (if (eq p '&key) nil (push p rslt))) (t (push (car p) rslt)))) (reverse rslt))) ;; RETURNIZE -- make a statement (list) end with a sal-return-from ;; ;; SAL returns nil from begin-end statement lists ;; (defun returnize (stmt) (let (rev) (setf rev (reverse stmt)) (setf expr (car rev)) ; last expression in list (cond ((and (consp expr) (eq (car expr) 'sal-return-from)) stmt) ; already ends in sal-return-from (t (reverse (cons (list 'sal-return-from *sal-fn-name* nil) rev)))))) (defun parse-declaration () (if (token-is :define) (parse-token)) ; SAL extension: "define" is optional (let (bindings setf-args formals parms stmt locals loc) (cond ((token-is :variable) (setf bindings (parse-bindings)) (setf loc *rslt*) ; the "variable" token (dolist (b bindings) (cond ((symbolp b) (push b setf-args) (push `(if (boundp ',b) ,b) setf-args)) (t (push (first b) setf-args) (push (second b) setf-args)))) (add-line-info-to-stmt (cons 'setf (reverse setf-args)) loc)) ((token-is :function) (parse-token) (if (token-is :id nil) (setf *sal-fn-name* (token-lisp (parse-token))) (errexit "function name expected here")) (setf locals *sal-local-variables*) (setf formals (parse-parms)) (setf stmt (parse-stmt)) ;; stmt may contain a return-from, so make this a progn or prog* (cond ((and (consp stmt) (not (eq (car stmt) 'progn)) (not (eq (car stmt) 'prog*))) (setf stmt (list 'progn stmt)))) ;; need return to pop traceback stack (setf stmt (returnize stmt)) ;; get list of parameter names (setf parms (get-parm-names formals)) (setf *sal-local-variables* locals) ;; build the defun (prog1 (list 'defun *sal-fn-name* formals (list 'sal-trace-enter (list 'quote *sal-fn-name*) (cons 'list parms) (list 'quote parms)) stmt) (setf *sal-fn-name* nil))) (t (errexit "bad syntax"))))) (defun parse-one-parm (kargs) ;; kargs is a flag indicating previous parameter was a keyword (all ;; the following parameters must then also be keyword parameters) ;; returns: ( ) or (nil ) ;; where is a keyward parameter name (nil if not a keyword parm) ;; is an expression for the default value ;; is the parameter name (if not a keyword parm) (let (key default-value id) (cond ((and kargs (token-is :id)) (errexit "positional parameter not allowed after keyword parameter")) ((token-is :id) ;(display "parse-one-1" (token-is :id) (car *sal-tokens*)) (setf id (token-lisp (parse-token))) (push id *sal-local-variables*) (list nil id)) ((token-is :key) (setf key (sal-string-to-symbol (token-string (parse-token)))) (cond ((or (token-is :co) (token-is :rp))) ; no default value (t (setf default-value (parse-sexpr)))) (list key default-value)) (kargs (errexit "expected keyword name")) (t (errexit "expected parameter name"))))) (defun parse-parms () ;(display "parse-parms" *sal-tokens*) (let (parms parm kargs expecting) (if (token-is :lp) (parse-token) ;; eat the left paren (errexit "expected left parenthesis")) (setf expecting (not (token-is :rp))) (while expecting (setf parm (parse-one-parm kargs)) ;(display "parm" parm) ;; returns list of (kargs . parm) (if (and (car parm) (not kargs)) ; kargs just set (push '&key parms)) (setf kargs (car parm)) ;; normally push the ; for keyword parms, push id and default value (push (if kargs parm (cadr parm)) parms) (if (token-is :co) (parse-token) (setf expecting nil))) (if (token-is :rp) (parse-token) (errexit "expected right parenthesis")) ;(display "parse-parms" (reverse parms)) (reverse parms))) (defun parse-bindings () (let (bindings bind) (setf *rslt* (parse-token)) ; skip "variable" or "with" ; return token as "extra" return value (setf bind (parse-bind)) (push (if (second bind) bind (car bind)) bindings) (while (token-is :co) (parse-token) (setf bind (parse-bind)) ;; if non-nil initializer, push (id expr) (push (if (second bind) bind (car bind)) bindings)) (reverse bindings))) (defun parse-bind () (let (id val) (if (token-is :id nil) (setf id (token-lisp (parse-token))) (errexit "expected a variable name")) (cond ((token-is :=) (parse-token) (setf val (parse-sexpr)))) (push id *sal-local-variables*) (list id val))) (defun parse-chdir () ;; assume next token is :chdir (or (token-is :chdir) (error "parse-chdir internal error")) (let (path loc) (setf loc (parse-token)) (setf path (parse-path)) (add-line-info-to-stmt (list 'setdir path) loc))) (defun parse-play () ;; assume next token is :play (or (token-is :play) (error "parse-play internal error")) (let ((loc (parse-token))) (add-line-info-to-stmt (list 'sal-play (parse-sexpr)) loc))) (defun parse-return () (or (token-is :return) (error "parse-return internal error")) (let (loc expr) ;; this seems to be a redundant test (if (and (null *sal-fn-name*) (not *audacity-top-level-return-flag*)) (errexit "Return must be inside a function body")) (setf loc (parse-token)) (setf expr (parse-sexpr)) (if *sal-fn-name* (add-line-info-to-stmt (list 'sal-return-from *sal-fn-name* expr) loc) (list 'defun 'main '() (list 'sal-trace-enter '(quote main) '() '()) (add-line-info-to-stmt expr loc))))) (defun parse-load () ;; assume next token is :load (or (token-is :load) (error "parse-load internal error")) (let (path args loc) (setf loc (parse-token)) (setf path (parse-path)) ; must return path or raise error (setf args (parse-keyword-args)) (add-line-info-to-stmt (cons 'sal-load (cons path args)) loc))) (defun parse-keyword-args () (let (args) (while (token-is :co) (parse-token) (cond ((token-is :key) (push (token-value) args) (push (parse-sexpr) args)))) (reverse args))) '(defun parse-system () ;; assume next token is :system (or (token-is :system) (error "parse-system internal error")) (let (path arg args) (parse-token) (setf path (parse-sexpr)) (list 'sal-system path))) (defun parse-path () (if (token-is '(:id :string)) (token-lisp (parse-token)) (errexit "path not found"))) (defun parse-print-display (token function) ;; assumes next token is :print (or (token-is token) (error "parse-print-display internal error")) (let (args arg loc) (setf loc (parse-token)) (setf arg (parse-sexpr)) (setf args (list arg)) (while (token-is :co) (parse-token) ; remove and ignore the comma (setf arg (parse-sexpr)) (push arg args)) (add-line-info-to-stmt (cons function (reverse args)) loc))) ;(defun parse-output () ; ;; assume next token is :output ; (or (token-is :output) (error "parse-output internal error")) ; (parse-token) ; (list 'sal-output (parse-sexpr))) (defun maybe-parse-block () (if (token-is :begin) (parse-block))) (defun parse-block () ;; assumes next token is :block (or (token-is :begin) (error "parse-block internal error")) (let (args stmts (locals *sal-local-variables*)) (parse-token) (cond ((token-is :with) (setf args (parse-bindings)))) (while (not (token-is :end)) (push (parse-stmt) stmts)) (parse-token) (setf stmts (reverse stmts)) ;(display "parse-block" args stmts) (setf *sal-local-variables* locals) (cons 'prog* (cons args stmts)))) ;; MAKE-STATEMENT-LIST -- convert stmt to a stmt list ;; ;; if it is a (PROGN ...) then return cdr -- it's already a list ;; otherwise, put single statement into a list ;; (defun make-statement-list (stmt) (cond ((atom stmt) (list stmt)) ((eq (car stmt) 'progn) (cdr stmt)) (t (list stmt)))) (setf *conditional-tokens* '(:if :when :unless)) (defun maybe-parse-conditional () (if (token-is *conditional-tokens*) (parse-conditional))) (defun parse-conditional () ;; assumes next token is :if (or (token-is *conditional-tokens*) (error "parse-conditional internal error")) (let (test then-stmt else-stmt if-token) (cond ((token-is :if) (setf if-token (parse-token)) (setf test (parse-sexpr if-token)) (if (not (token-is :then)) (errexit "expected then after if")) (parse-token) (if (not (token-is :else)) ;; no then statement (setf then-stmt (parse-stmt))) (cond ((token-is :else) (parse-token) (setf else-stmt (parse-stmt)))) ;(display "cond" test then-stmt else-stmt) (if else-stmt (list 'if test then-stmt else-stmt) (list 'if test then-stmt))) ((token-is :when) (parse-token) (setf test (parse-sexpr)) (setf then-stmt (parse-stmt)) (cons 'when (cons test (make-statement-list then-stmt)))) ((token-is :unless) (parse-token) (setf test (parse-sexpr)) (setf else-stmt (parse-stmt)) (cons 'unless (cons test (make-statement-list else-stmt))))))) (defun maybe-parse-assignment () (if (token-is :set) (parse-assignment))) (defun parse-assignment () ;; first token must be set (or (token-is :set) (error "parse-assignment internal error")) (let (assignments rslt vref op expr set-token) (setf set-token (parse-token)) (push (parse-assign) assignments) ; returns (target op value) (while (token-is :co) (parse-token) ; skip the comma (push (parse-assign) assignments)) ; now assignments is ((target op value) (target op value)...) (dolist (assign assignments) (setf vref (first assign) op (second assign) expr (third assign)) (cond ((eq op '=)) ((eq op '-=) (setf expr `(diff ,vref ,expr))) ((eq op '+=) (setf expr `(sum ,vref ,expr))) ((eq op '*=) (setq expr `(mult ,vref ,expr))) ((eq op '/=) (setq expr `(/ ,vref ,expr))) ((eq op '&=) (setq expr `(nconc ,vref (list ,expr)))) ((eq op '@=) (setq expr `(cons ,expr ,vref))) ((eq op '^=) (setq expr `(nconc ,vref (append ,expr nil)))) ((eq op '<=) (setq expr `(min ,vref ,expr))) ((eq op '>=) (setq expr `(max ,vref ,expr))) (t (errexit (format nil "unknown assigment operator ~A" op)))) (push (list 'setf vref expr) rslt)) (setf rslt (add-line-info-to-stmts rslt set-token)) (if (> (length rslt) 1) (cons 'progn rslt) (car rslt)))) ;; PARSE-ASSIGN -- based on parse-bind, but with different operators ;; ;; allows arbitrary term on left because it could be an array ;; reference. After parsing, we can check that the target of the ;; assignment is either an identifier or an (aref ...) ;; (defun parse-assign () (let ((lhs (parse-term) op val)) (cond ((token-is '(:= :-= :+= :*= :/= :&= :@= :^= :<= :>=)) (setf op (parse-token)) (setf op (if (eq (token-type op) ':=) '= (token-lisp op))) (setf val (parse-sexpr)))) (cond ((and (consp lhs) (eq (car lhs) 'aref))) ;; aref good ((symbolp lhs)) ;; id good (t (errexit "expected a variable name or array reference"))) (list lhs op val))) (defun maybe-parse-loop () (if (token-is :loop) (parse-loop))) ;; loops are compiled to do* ;; bindings go next as usual, but bindings include for variables ;; and repeat is converted to a for +count+ from 0 to ;; stepping is done after statement ;; termination clauses are combined with OR and ;; finally goes after termination ;; statement goes in do* body ;; (defun parse-loop () (or (token-is :loop) (error "parse-loop: internal error")) (let (bindings termination-tests stmts sexpr rslt finally loc (locals *sal-local-variables*)) (parse-token) ; skip "loop" (if (token-is :with) (setf bindings (reverse (parse-bindings)))) (while (token-is '(:repeat :for)) (cond ((token-is :repeat) (setf loc (parse-token)) (push (list 'sal:loopcount 0 '(1+ sal:loopcount)) bindings) (setf sexpr (parse-sexpr loc)) ; get final count expression (push (list 'sal:loopfinal sexpr) bindings) (push '(>= sal:loopcount sal:loopfinal) termination-tests)) ((token-is :for) (setf rslt (parse-for-clause)) ; there can be multiple bindings, build bindings in reverse (cond ((first rslt) (setf bindings (append (reverse (first rslt)) bindings)))) (if (second rslt) (push (second rslt) termination-tests))))) (while (token-is '(:while :until)) (cond ((token-is :while) (setf loc (parse-token)) (push (list 'not (parse-sexpr loc)) termination-tests)) ((token-is :until) (setf loc (parse-token)) (push (parse-sexpr loc) termination-tests)))) ; (push (parse-stmt) stmts) (while (not (token-is '(:end :finally))) (push (parse-stmt) stmts)) (cond ((token-is :finally) (parse-token) ; skip "finally" (setf finally (parse-stmt)))) (if (token-is :end) (parse-token) (errexit "expected end after loop")) (setf *sal-local-variables* locals) `(do* ,(reverse bindings) ,(list (or-ize (reverse termination-tests)) finally) ,@(reverse stmts)))) ;; OR-IZE -- compute the OR of a list of expressions ;; (defun or-ize (exprs) (if (> 1 (length exprs)) (cons 'or exprs) (car exprs))) (defun maybe-parse-exec () (if (token-is :exec) (parse-exec))) (defun parse-exec () (or (token-is :exec) (error "parse-exec internal error")) (let ((loc (parse-token))) ; skip the :exec (parse-sexpr loc))) (defun maybe-parse-exit () (if (token-is :exit) (parse-exit))) (defun parse-exit () (let (tok loc) (or (token-is :exit) (error "parse-exit internal error")) (setf loc (parse-token)) ; skip the :exit (cond ((token-is :id) (setf tok (parse-token)) (cond ((eq (token-lisp tok) 'nyquist) (add-line-info-to-stmt '(exit) loc)) ((eq (token-lisp tok) 'sal) (add-line-info-to-stmt '(sal-exit) loc)) (t (errexit "expected \"nyquist\" or \"sal\" after \"exit\"")))) (t (add-line-info-to-stmt '(sal-exit) loc))))) ;; PARSE-FOR-CLAUSE - returns (bindings term-test) ;; (defun parse-for-clause () (or (token-is :for) (error "parse-for-clause: internal error")) (let (id init next rslt binding term-test list-id loc) (setf loc (parse-token)) ; skip for (if (token-is :id) (setf id (token-lisp (parse-token))) (errexit "expected identifier after for")) (cond ((token-is :=) ;; if the clause is just for id = expr, then assume that ;; expr depends on something that changes each iteration: ;; recompute and assign expr to id each time around (parse-token) ; skip "=" (setf init (parse-sexpr loc)) (cond ((token-is :then) (parse-token) ; skip "then" (setf binding (list id init (parse-sexpr loc)))) (t (setf binding (list id init init)))) (setf binding (list binding))) ((token-is :in) (setf loc (parse-token)) ; skip "in" (setf list-id (intern (format nil "SAL:~A-LIST" id))) (setf binding (list (list list-id (parse-sexpr loc) (list 'cdr list-id)) (list id (list 'car list-id) (list 'car list-id)))) (setf term-test (list 'null list-id))) ((token-is :over) (setf loc (parse-token)) ; skip "over" (setf start (parse-sexpr loc)) #| (cond ((token-is :by) (parse-token) ; skip "by" (parse-sexpr))) ;-- I don't know what "by" means - RBD |# (setf list-id (intern (format nil "SAL:~A-PATTERN" id))) (setf binding (list (list list-id start) (list id (list 'next list-id) (list 'next list-id))))) ((token-is '(:from :below :to :above :downto :by)) (cond ((token-is :from) (setf loc (parse-token)) ; skip "from" (setf init (parse-sexpr loc))) (t (setf init 0))) (cond ((token-is :below) (setf loc (parse-token)) ; skip "below" (setf term-test (list '>= id (parse-sexpr loc)))) ((token-is :to) (setf loc (parse-token)) ; skip "to" (setf term-test (list '> id (parse-sexpr loc)))) ((token-is :above) (setf loc (parse-token)) ; skip "above" (setf term-test (list '<= id (parse-sexpr loc)))) ((token-is :downto) (setf loc (parse-token)) ; skip "downto" (setf term-test (list '< id (parse-sexpr loc))))) (cond ((token-is :by) (setf loc (parse-token)) ; skip "by" (setf binding (list id init (list '+ id (parse-sexpr loc))))) ((or (null term-test) (and term-test (member (car term-test) '(>= >)))) (setf binding (list id init (list '1+ id)))) (t ; loop goes down because of "above" or "downto" ; (display "for step" term-test) (setf binding (list id init (list '1- id))))) (setf binding (list binding))) (t (errexit "for statement syntax error"))) (list binding term-test))) ;; parse-sexpr works by building a list: (term op term op term ...) ;; later, the list is parsed again using operator precedence rules (defun parse-sexpr (&optional loc) (let (term rslt) (push (parse-term) rslt) (while (token-is *sal-operators*) (push (token-type (parse-token)) rslt) (push (parse-term) rslt)) (setf rslt (reverse rslt)) ;(display "parse-sexpr before inf->pre" rslt) (setf rslt (if (consp (cdr rslt)) (inf->pre rslt) (car rslt))) (if loc (setf rslt (add-line-info-to-expression rslt loc))) rslt)) (defun get-lisp-op (op) (third (assoc op +operators+))) ;; a term is , or ;; ( ), or ;; ? ( , , ), or ;; , or ;; ( ), or ;; [ ] ;; Since any term can be followed by indexing, handle everything ;; but the indexing here in parse-term-1, then write parse-term ;; to do term-1 followed by indexing operations ;; (defun parse-term-1 () (let (sexpr id) (cond ((token-is '(:- :!)) (list (token-lisp (parse-token)) (parse-term))) ((token-is :lp) (parse-token) ; skip left paren (setf sexpr (parse-sexpr)) (if (token-is :rp) (parse-token) (errexit "right parenthesis not found")) sexpr) ((token-is :?) (parse-ifexpr)) ((token-is :lc) (list 'quote (parse-list))) ((token-is '(:int :float :bool :list :string)) ;(display "parse-term int float bool list string" (car *sal-tokens*)) (token-lisp (parse-token))) ((token-is :id) ;; aref or funcall (setf id (token-lisp (parse-token))) ;; array indexing was here, but that only allows [x] after ;; identifiers. Move this to expression parsing. (cond ((token-is :lp) (parse-token) (setf sexpr (cons id (parse-pargs t))) (if (token-is :rp) (parse-token) (errexit "right paren not found")) sexpr) (t id))) (t (errexit "expression not found"))))) (defun parse-term () (let ((term (parse-term-1))) ; (display "parse-term" term (token-is :lb)) (while (token-is :lb) (parse-token) (setf term (list 'aref term (parse-sexpr))) (if (token-is :rb) (parse-token) (errexit "right bracket not found"))) term)) (defun parse-ifexpr () (or (token-is :?) (error "parse-ifexpr internal error")) (let (condition then-sexpr else-sexpr) (parse-token) ; skip the :? (if (token-is :lp) (parse-token) (errexit "expected left paren")) (setf condition (parse-sexpr)) (if (token-is :co) (parse-token) (errexit "expected comma")) (setf then-sexpr (parse-sexpr)) (if (token-is :co) (parse-token) (errexit "expected comma")) (setf else-sexpr (parse-sexpr)) (if (token-is :rp) (parse-token) (errexit "expected left paren")) (list 'if condition then-sexpr else-sexpr))) (defun keywordp (s) (and (symbolp s) (eq (type-of (symbol-name s)) 'string) (equal (char (symbol-name s) 0) #\:))) (defun functionp (x) (eq (type-of x) 'closure)) (defun parse-pargs (keywords-allowed) ;; get a list of sexprs. If keywords-allowed, then at any point ;; the arg syntax can switch from [ ]* to ;; [ ]* ;; also if keywords-allowed, it's a function call and the ;; list may be empty. Otherwise, it's a list of indices and ;; the list may not be empty (let (pargs keyword-expected sexpr keyword) (if (and keywords-allowed (token-is :rp)) nil ; return empty parameter list (loop ; look for one or more [keyword] sexpr ; optional keyword test (setf keyword nil) ;(display "pargs" (car *sal-tokens*)) (if (token-is :key) (setf keyword (token-lisp (parse-token)))) ; (display "parse-pargs" keyword) ; did we need a keyword? (if (and keyword-expected (not keyword)) (errexit "expected keyword")) ; was a keyword legal (if (and keyword (not keywords-allowed)) (errexit "keyword not allowed here")) (setf keyword-expected keyword) ; once we get a keyword, we need ; one before each sexpr ; now find sexpr (setf sexpr (parse-sexpr)) (if keyword (push keyword pargs)) (push sexpr pargs) ; (display "parse-pargs" keyword sexpr pargs) (cond ((token-is :co) (parse-token)) (t (return (reverse pargs)))))))) ;; PARSE-LIST -- parse list in braces {}, return list not quoted list ;; (defun parse-list () (or (token-is :lc) (error "parse-list internal error")) (let (elts) (parse-token) (while (not (token-is :rc)) (cond ((token-is '(:int :float :id :bool :key :string)) (push (token-lisp (parse-token)) elts)) ((token-is :lc) (push (parse-list) elts)) (t (errexit "expected list element or right brace")))) (parse-token) (reverse elts))) (defparameter *op-weights* '( (:\| 1) (:& 2) (:! 3) (:= 4) (:!= 4) (:> 4) (:>= 4) (:< 4) (:<= 4) (:~= 4) ; general equality (:+ 5) (:- 5) (:% 5) (:* 6) (:/ 6) (:^ 7) (:~ 8) (:~~ 8) (:@ 8) (:@@ 8))) (defun is-op? (x) ;; return op weight if x is operator (let ((o (assoc (if (listp x) (token-type x) x) *op-weights*))) (and o (cadr o)))) (defun inf->pre (inf) ;; this does NOT rewrite subexpressions because parser applies rules ;; depth-first so subexprs are already processed (let (op lh rh w1) (if (consp inf) (do () ((null inf) lh) (setq op (car inf)) ; look at each element of in (pop inf) (setq w1 (is-op? op)) (cond ((numberp w1) ; found op (w1 is precedence) (do ((w2 nil) (ok t) (li (list))) ((or (not inf) (not ok)) (setq rh (inf->pre (nreverse li))) (setq lh (if lh (list (get-lisp-op op) lh rh) (list (get-lisp-op op) rh nil)))) (setq w2 (is-op? (first inf))) (cond ((and w2 (<= w2 w1)) (setq ok nil)) (t (push (car inf) li) (pop inf))))) (t (setq lh op)))) inf)))