;;; ********************************************************************** ;;; Copyright (C) 2006 Rick Taube ;;; This program is free software; you can redistribute it and/or ;;; modify it under the terms of the Lisp Lesser Gnu Public License. ;;; See http://www.cliki.net/LLGPL for the text of this agreement. ;;; ********************************************************************** ;;; $Revision: 1.2 $ ;;; $Date: 2009-03-05 17:42:25 $ ;; DATA STRUCTURES AND ALGORITHMS (for sal.lsp and parse.lsp) ;; ;; TOKENIZE converts source language (a string) into a list of tokens ;; each token is represented as follows: ;; (:TOKEN ) ;; where is one of: ;; :id -- an identifier ;; :lp -- left paren ;; :rp -- right paren ;; :+, etc. -- operators ;; :int -- an integer ;; :float -- a float ;; :print, etc. -- a reserved word ;; is the source string for the token ;; is the column of the string ;; and are ?? ;; Tokenize uses a list of reserved words extracted from terminals in ;; the grammar. Each reserved word has an associated token type, but ;; all other identifiers are simply of type :ID. ;; ;; *** WHY REWRITE THE ORIGINAL PARSER? *** ;; Originally, the code interpreted a grammar using a recursive pattern ;; matcher, but XLISP does not have a huge stack and there were ;; stack overflow problems because even relatively small expressions ;; went through a very deep nesting of productions. E.g. ;; "print note(between(30,odds(.5, 60, 90)))" 0 t nil))" was at recursion ;; level 46 when the stack overflowed. The stack depth is 2000 or 4000, ;; but all locals and parameters get pushed here, so since PARSE is the ;; recursive function and it has lots of parameters and locals, it appears ;; to use 80 elements in the stack per call. ;; *** END *** ;; ;; The grammar for the recursive descent parser: ;; note: [ ] means optional , * means 0 or more of ;; ;; = | ;; = | | | ;; = { * } ;; = | | ;; = ;; = ? "(" , [ , ] ")" ;; = ;; = "(" [ ] ")" ;; = [ , ]* ;; = | ;; = + | - | "*" | / | % | ^ | = | != | ;; "<" | ">" | "<=" | ">=" | ~= | ! | & | "|" ;; = [ ]* ;; = <-> | | "(" ")" | ;; | | | | | ;; = | | class ;; = | | | | | ;; = exec ;; = | | ;; = define ;; = | ;; = variable ;; = [ , ]* ;; = [ <=> ] ;; = "(" [ ] ")" ;; = [ , ]* ;; this is new: key: expression for keyword parameter ;; = | [ ] ;; = | | | ;; | ;; = begin [ with [ ]* end ;; = if then [ ] [ else ] | ;; when | unless ;; = set [ , ]* ;; = ( | ) ;; = = | += | *= | &= | @= | ^= | "<=" | ">=" ;; = | chdir | ;; system | play ;; (note: system was removed) ;; = load [ , ]* ;; = | ;; = print [ , ]* | ;; output ;; = loop [ with ] [ ]* ;; [ ]* [ ]+ ;; [ finally ] end ;; = repeat | ;; for = [ then ] | ;; for in | ;; for over [ by ] | ;; for [ from ] ;; [ ( below | to | above | downto ) ] ;; [ by ] | ;; = while | until ;; = return ;(in-package cm) ; (progn (cd "/Lisp/sal/") (load "parse.lisp") (load "sal.lisp")) (setfn defconstant setf) (setfn defparameter setf) (setfn defmethod defun) (setfn defvar setf) (setfn values list) (if (not (boundp '*sal-secondary-prompt*)) (setf *sal-secondary-prompt* t)) (if (not (boundp '*sal-xlispbreak*)) (setf *sal-xlispbreak* nil)) (defun sal-trace-enter (fn &optional argvals argnames) (push (list fn *sal-line* argvals argnames) *sal-call-stack*)) (defun sal-trace-exit () (setf *sal-line* (second (car *sal-call-stack*))) (pop *sal-call-stack*)) ;; SAL-RETURN-FROM is generated by Sal compiler and ;; performs a return as well as a sal-trace-exit() ;; (defmacro sal-return-from (fn val) `(prog ((sal:return-value ,val)) (setf *sal-line* (second (car *sal-call-stack*))) (pop *sal-call-stack*) (return-from ,fn sal:return-value))) (setf *sal-traceback* t) (defun sal-traceback (&optional (file t) &aux comma name names line) (format file "Call traceback:~%") (setf line *sal-line*) (dolist (frame *sal-call-stack*) (setf comma "") (format file " ~A" (car frame)) (cond ((symbolp (car frame)) (format file "(") (setf names (cadddr frame)) (dolist (arg (caddr frame)) (setf name (car names)) (format file "~A~% ~A = ~A" comma name arg) (setf names (cdr names)) (setf comma ",")) (format file ") at line ~A~%" line) (setf line (second frame))) (t (format file "~%"))))) '(defmacro defgrammer (sym rules &rest args) `(defparameter ,sym (make-grammer :rules ',rules ,@args))) '(defun make-grammer (&key rules literals) (let ((g (list 'a-grammer rules literals))) (grammer-initialize g) g)) '(defmethod grammer-initialize (obj) (let (xlist) ;; each literal is (:name "name") (cond ((grammer-literals obj) (dolist (x (grammer-literals obj)) (cond ((consp x) (push x xlist)) (t (push (list (string->keyword (string-upcase (string x))) (string-downcase (string x))) xlist))))) (t (dolist (x (grammer-rules obj)) (cond ((terminal-rule? x) (push (list (car x) (string-downcase (subseq (string (car x)) 1))) xlist)))))) (set-grammer-literals obj (reverse xlist)))) '(setfn grammer-rules cadr) '(setfn grammer-literals caddr) '(defun set-grammer-literals (obj val) (setf (car (cddr obj)) val)) '(defun is-grammer (obj) (and (consp obj) (eq (car obj) 'a-grammer))) (defun string->keyword (str) (intern (strcat ":" (string-upcase str)))) (defun terminal-rule? (rule) (or (null (cdr rule)) (not (cadr rule)))) (load "sal-parse.lsp" :verbose nil) (defparameter *sal-print-list* t) (defun sal-printer (x &key (stream *standard-output*) (add-space t) (in-list nil)) (let ((*print-case* ':downcase)) (cond ((and (consp x) *sal-print-list*) (write-char #\{ stream) (do ((items x (cdr items))) ((null items)) (sal-printer (car items) :stream stream :add-space (cdr items) :in-list t) (cond ((cdr items) (cond ((not (consp (cdr items))) (princ " " stream) (sal-printer (cdr items) :stream stream :add-space nil) (setf items nil)))))) (write-char #\} stream)) ((not x) (princ "#f" stream) ) ((eq x t) (princ "#t" stream)) (in-list (prin1 x stream)) (t (princ x stream))) (if add-space (write-char #\space stream)))) (defparameter *sal-printer* #'sal-printer) (defun sal-message (string &rest args) (format t "~&; ") (apply #'format t string args)) ;; sal-print has been modified from the original SAL to print items separated ;; by spaces (no final trailing space) and followed by a newline. (defun sal-print (&rest args) (do ((items args (cdr items))) ((null items)) ;; add space unless we are at the last element (funcall *sal-printer* (car items) :add-space (cdr items))) (terpri) (values)) (defmacro keyword (sym) `(str-to-keyword (symbol-name ',sym))) (defun plus (&rest nums) (apply #'+ nums)) (defun minus (num &rest nums) (apply #'- num nums)) (defun times (&rest nums) (apply #'* nums)) (defun divide (num &rest nums) (apply #'/ num nums)) ;; implementation of infix "!=" operator (defun not-eql (x y) (not (eql x y))) ; dir "*.* ; chdir ; load "rts.sys" (defun sal-chdir ( dir) (cd (expand-path-name dir)) (sal-message "Directory: ~A" (pwd)) (values)) ;;; sigh, not all lisps support ~/ directory components. (defun expand-path-name (path &optional absolute?) (let ((dir (pathname-directory path))) (flet ((curdir () (truename (make-pathname :directory (pathname-directory *default-pathname-defaults*))))) (cond ((null dir) (if (equal path "~") (namestring (user-homedir-pathname)) (if absolute? (namestring (merge-pathnames path (curdir))) (namestring path)))) ((eql (car dir) ':absolute) (namestring path)) (t (let* ((tok (second dir)) (len (length tok))) (if (char= (char tok 0) #\~) (let ((uhd (pathname-directory (user-homedir-pathname)))) (if (= len 1) (namestring (make-pathname :directory (append uhd (cddr dir)) :defaults path)) (namestring (make-pathname :directory (append (butlast uhd) (list (subseq tok 1)) (cddr dir)) :defaults path)))) (if absolute? (namestring (merge-pathnames path (curdir))) (namestring path))))))))) (defun sal-load (filename &key (verbose t) print) (progv '(*sal-input-file-name*) (list filename) (prog (file extended-name) ;; first try to load exact name (cond ((setf file (open filename)) (close file) ;; found it: close it and load it (return (generic-loader filename verbose print)))) ;; try to load name with ".sal" or ".lsp" (cond ((string-search "." filename) ; already has extension nil) ; don't try to add another extension ((setf file (open (strcat filename ".sal"))) (close file) (return (sal-loader (strcat filename ".sal") :verbose verbose :print print))) ((setf file (open (strcat filename ".lsp"))) (close file) (return (lisp-loader filename :verbose verbose :print print)))) ;; search for file as is or with ".lsp" on path (setf fullpath (find-in-xlisp-path filename)) (cond ((and (not fullpath) ; search for file.sal on path (not (string-search "." filename))) ; no extension yet (setf fullpath (find-in-xlisp-path (strcat filename ".sal"))))) (cond ((null fullpath) (format t "sal-load: could not find ~A~%" filename)) (t (return (generic-loader filename verbose print))))))) ;; GENERIC-LOADER -- load a sal or lsp file based on extension ;; ;; assumes that file exists, and if no .sal extension, type is Lisp ;; (defun generic-loader (fullpath verbose print) (cond ((has-extension fullpath ".sal") (sal-loader fullpath :verbose verbose :print print)) (t (lisp-loader fullpath :verbose verbose :print print)))) #| (defun sal-load (filename &key (verbose t) print) (progv '(*sal-input-file-name*) (list filename) (let (file extended-name) (cond ((has-extension filename ".sal") (sal-loader filename :verbose verbose :print print)) ((has-extension filename ".lsp") (lisp-load filename :verbose verbose :print print)) ;; see if we can just open the exact filename and load it ((setf file (open filename)) (close file) (lisp-load filename :verbose verbose :print print)) ;; if not, then try loading file.sal and file.lsp ((setf file (open (setf *sal-input-file-name* (strcat filename ".sal")))) (close file) (sal-loader *sal-input-file-name* :verbose verbose :print print)) ((setf file (open (setf *sal-input-file-name* (strcat filename ".lsp")))) (close file) (lisp-load *sal-input-file-name* :verbose verbose :print print)) (t (format t "sal-load: could not find ~A~%" filename)))))) |# (defun lisp-loader (filename &key (verbose t) print) (if (load filename :verbose verbose :print print) nil ; be quiet if things work ok (format t "error loading lisp file ~A~%" filename))) (defun has-extension (filename ext) (let ((loc (string-search ext filename :start (max 0 (- (length filename) (length ext)))))) (not (null loc)))) ; coerce to t or nil (defmacro sal-at (s x) (list 'at x s)) (defmacro sal-at-abs (s x) (list 'at-abs x s)) (defmacro sal-stretch (s x) (list 'stretch x s)) (defmacro sal-stretch-abs (s x) (list 'stretch-abs x s)) ;; splice every pair of lines (defun strcat-pairs (lines) (let (rslt) (while lines (push (strcat (car lines) (cadr lines)) rslt) (setf lines (cddr lines))) (reverse rslt))) (defun strcat-list (lines) ;; like (apply 'strcat lines), but does not use a lot of stack ;; When there are too many lines, XLISP will overflow the stack ;; because args go on the stack. (let (r) (while (> (setf len (length lines)) 1) (if (oddp len) (setf lines (cons "" lines))) (setf lines (strcat-pairs lines))) ; if an empty list, return "", else list has one string: return it (if (null lines) "" (car lines)))) (defun sal-loader (filename &key verbose print) (let ((input "") (file (open filename)) line lines) (cond (file (push filename *loadingfiles*) (while (setf line (read-line file)) (push line lines) (push "\n" lines)) (close file) (setf input (strcat-list (reverse lines))) (sal-trace-enter (strcat "Loading " filename)) (sal-compile input t t filename) (pop *loadingfiles*) (sal-trace-exit)) (t (format t "error loading SAL file ~A~%" filename))))) ; SYSTEM command is not implemented ;(defun sal-system (sys &rest pairs) ; (apply #'use-system sys pairs)) (defun load-sal-file (file) (with-open-file (f file :direction :input) (let ((input (make-array '(512) :element-type 'character :fill-pointer 0 :adjustable t))) (loop with flag for char = (read-char f nil ':eof) until (or flag (eql char ':eof)) do (when (char= char #\;) (loop do (setq char (read-char f nil :eof)) until (or (eql char :eof) (char= char #\newline)))) (unless (eql char ':eof) (vector-push-extend char input))) (sal input :pattern :command-sequence)))) (defmacro sal-play (snd) (if (stringp snd) `(play-file ,snd) `(play ,snd))) (if (not (boundp '*sal-compiler-debug*)) (setf *sal-compiler-debug* nil)) (defmacro sal-simrep (variable iterations body) `(simrep (,variable ,iterations) ,body)) (defmacro sal-seqrep (variable iterations body) `(seqrep (,variable ,iterations) ,body)) ;; function called in sal programs to exit the sal read-compile-run-print loop (defun sal-exit () (setf *sal-exit* t)) (setf *sal-call-stack* nil) ;; read-eval-print loop for sal commands (defun sal () (progv '(*breakenable* *tracenable* *sal-exit* *sal-mode*) (list *sal-break* nil nil t) (let (input line) (setf *sal-call-stack* nil) (read-line) ; read the newline after the one the user ; typed to invoke this fn (princ "Entering SAL mode ...\n"); (while (not *sal-exit*) (princ "\nSAL> ") (sal-trace-enter "SAL top-level command interpreter") ;; get input terminated by two returns (setf input "") (while (> (length (setf line (read-line))) 0) (if *sal-secondary-prompt* (princ " ... ")) (setf input (strcat input "\n" line))) ;; input may have an extra return, remaining from previous read ;; if so, trim it because it affects line count in error messages (if (and (> (length input) 0) (char= (char input 0) #\newline)) (setf input (subseq input 1))) (sal-compile input t nil "") (sal-trace-exit)) (princ "Returning to Lisp ...\n"))) ;; in case *xlisp-break* or *xlisp-traceback* was set from SAL, impose ;; them here (cond ((not *sal-mode*) (setf *breakenable* *xlisp-break*) (setf *tracenable* *xlisp-traceback*))) t) (defun sal-error-output (stack) (if *sal-traceback* (sal-traceback)) (setf *sal-call-stack* stack)) ;; clear the stack ;; when true, top-level return statement is legal and compiled into MAIN (setf *audacity-top-level-return-flag* nil) ;; SAL-COMPILE-AUDACITY -- special treatment of RETURN ;; ;; This works like SAL-COMPILE, but if there is a top-level ;; return statement (not normally legal), it is compiled into ;; a function named MAIN. This is a shorthand for Audacity plug-ins ;; (defun sal-compile-audacity (input eval-flag multiple-statements filename) (progv '(*audacity-top-level-return-flag*) '(t) (sal-compile input eval-flag multiple-statements filename))) ;; SAL-COMPILE -- translate string or token list to lisp and eval ;; ;; input is either a string or a token list ;; eval-flag tells whether to evaluate the program or return the lisp ;; multiple-statements tells whether the input can contain multiple ;; top-level units (e.g. from a file) or just one (from command line) ;; returns: ;; if eval-flag, then nothing is returned ;; otherwise, returns nil if an error is encountered ;; otherwise, returns a list (PROGN p1 p2 p3 ...) where pn are lisp ;; expressions ;; (defun sal-compile (input eval-flag multiple-statements filename) ;; save some globals because eval could call back recursively (progv '(*sal-tokens* *sal-input* *sal-input-text*) '(nil nil nil) (let (output remainder rslt stack) (setf stack *sal-call-stack*) ;; if first input char is "(", then eval as a lisp expression: ;(display "sal-compile" input)(setf *sal-compiler-debug* t) (cond ((input-starts-with-open-paren input) ;(print "input is lisp expression") (errset (print (eval (read (make-string-input-stream input)))) t)) (t ;; compile SAL expression(s): (loop (setf output (sal-parse nil nil input multiple-statements filename)) (cond ((first output) ; successful parse (setf remainder *sal-tokens*) (setf output (second output)) (when *sal-compiler-debug* (terpri) (pprint output)) (cond (eval-flag ;; evaluate the compiled code (cond ((null (errset (eval output) t)) (sal-error-output stack) (return)))) ;; stop on error (t (push output rslt))) ;(display "sal-compile after eval" ; remainder *sal-tokens*) ;; if there are statements left over, maybe compile again (cond ((and multiple-statements remainder) ;; move remainder to input and iterate (setf input remainder)) ;; see if we've compiled everything ((and (not eval-flag) (not remainder)) (return (cons 'progn (reverse rslt)))) ;; if eval but no more input, return ((not remainder) (return)))) (t ; error encountered (return))))))))) ;; SAL just evaluates lisp expression if it starts with open-paren, ;; but sometimes reader reads previous newline(s), so here we ;; trim off initial newlines and check if first non-newline is open-paren (defun input-starts-with-open-paren (input) (let ((i 0)) (while (and (stringp input) (> (length input) i) (eq (char input i) #\newline)) (incf i)) (and (stringp input) (> (length input) i) (eq (char input i) #\())))