shell bypass 403
;;; ECMAScript for Guile
;; Copyright (C) 2009, 2011 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 ecmascript compile-tree-il)
#:use-module (language tree-il)
#:use-module (ice-9 receive)
#:use-module (system base pmatch)
#:use-module (srfi srfi-1)
#:export (compile-tree-il))
(define-syntax-rule (-> (type arg ...))
`(type ,arg ...))
(define-syntax-rule (@implv sym)
(-> (@ '(language ecmascript impl) 'sym)))
(define-syntax-rule (@impl sym arg ...)
(-> (apply (@implv sym) arg ...)))
(define (empty-lexical-environment)
'())
(define (econs name gensym env)
(acons name (-> (lexical name gensym)) env))
(define (lookup name env)
(or (assq-ref env name)
(-> (toplevel name))))
(define (compile-tree-il exp env opts)
(values
(parse-tree-il
(-> (begin (@impl js-init)
(comp exp (empty-lexical-environment)))))
env
env))
(define (location x)
(and (pair? x)
(let ((props (source-properties x)))
(and (not (null? props))
props))))
;; for emacs:
;; (put 'pmatch/source 'scheme-indent-function 1)
(define-syntax-rule (pmatch/source x clause ...)
(let ((x x))
(let ((res (pmatch x
clause ...)))
(let ((loc (location x)))
(if loc
(set-source-properties! res (location x))))
res)))
(define current-return-tag (make-parameter #f))
(define (return expr)
(-> (abort (or (current-return-tag) (error "return outside function"))
(list expr)
(-> (const '())))))
(define (with-return-prompt body-thunk)
(let ((tag (gensym "return")))
(parameterize ((current-return-tag
(-> (lexical 'return tag))))
(-> (let '(return) (list tag)
(list (-> (apply (-> (primitive 'make-prompt-tag)))))
(-> (prompt (current-return-tag)
(body-thunk)
(let ((val (gensym "val")))
(-> (lambda-case
`(((k val) #f #f #f () (,(gensym) ,val))
,(-> (lexical 'val val)))))))))))))
(define (comp x e)
(let ((l (location x)))
(define (let1 what proc)
(let ((sym (gensym)))
(-> (let (list sym) (list sym) (list what)
(proc sym)))))
(define (begin1 what proc)
(let1 what (lambda (v)
(-> (begin (proc v)
(-> (lexical v v)))))))
(pmatch/source x
(null
;; FIXME, null doesn't have much relation to EOL...
(-> (const '())))
(true
(-> (const #t)))
(false
(-> (const #f)))
((number ,num)
(-> (const num)))
((string ,str)
(-> (const str)))
(this
(@impl get-this))
((+ ,a)
(-> (apply (-> (primitive '+))
(@impl ->number (comp a e))
(-> (const 0)))))
((- ,a)
(-> (apply (-> (primitive '-)) (-> (const 0)) (comp a e))))
((~ ,a)
(@impl bitwise-not (comp a e)))
((! ,a)
(@impl logical-not (comp a e)))
((+ ,a ,b)
(-> (apply (-> (primitive '+)) (comp a e) (comp b e))))
((- ,a ,b)
(-> (apply (-> (primitive '-)) (comp a e) (comp b e))))
((/ ,a ,b)
(-> (apply (-> (primitive '/)) (comp a e) (comp b e))))
((* ,a ,b)
(-> (apply (-> (primitive '*)) (comp a e) (comp b e))))
((% ,a ,b)
(@impl mod (comp a e) (comp b e)))
((<< ,a ,b)
(@impl shift (comp a e) (comp b e)))
((>> ,a ,b)
(@impl shift (comp a e) (comp `(- ,b) e)))
((< ,a ,b)
(-> (apply (-> (primitive '<)) (comp a e) (comp b e))))
((<= ,a ,b)
(-> (apply (-> (primitive '<=)) (comp a e) (comp b e))))
((> ,a ,b)
(-> (apply (-> (primitive '>)) (comp a e) (comp b e))))
((>= ,a ,b)
(-> (apply (-> (primitive '>=)) (comp a e) (comp b e))))
((in ,a ,b)
(@impl has-property? (comp a e) (comp b e)))
((== ,a ,b)
(-> (apply (-> (primitive 'equal?)) (comp a e) (comp b e))))
((!= ,a ,b)
(-> (apply (-> (primitive 'not))
(-> (apply (-> (primitive 'equal?))
(comp a e) (comp b e))))))
((=== ,a ,b)
(-> (apply (-> (primitive 'eqv?)) (comp a e) (comp b e))))
((!== ,a ,b)
(-> (apply (-> (primitive 'not))
(-> (apply (-> (primitive 'eqv?))
(comp a e) (comp b e))))))
((& ,a ,b)
(@impl band (comp a e) (comp b e)))
((^ ,a ,b)
(@impl bxor (comp a e) (comp b e)))
((bor ,a ,b)
(@impl bior (comp a e) (comp b e)))
((and ,a ,b)
(-> (if (@impl ->boolean (comp a e))
(comp b e)
(-> (const #f)))))
((or ,a ,b)
(let1 (comp a e)
(lambda (v)
(-> (if (@impl ->boolean (-> (lexical v v)))
(-> (lexical v v))
(comp b e))))))
((if ,test ,then ,else)
(-> (if (@impl ->boolean (comp test e))
(comp then e)
(comp else e))))
((if ,test ,then)
(-> (if (@impl ->boolean (comp test e))
(comp then e)
(@implv *undefined*))))
((postinc (ref ,foo))
(begin1 (comp `(ref ,foo) e)
(lambda (var)
(-> (set! (lookup foo e)
(-> (apply (-> (primitive '+))
(-> (lexical var var))
(-> (const 1)))))))))
((postinc (pref ,obj ,prop))
(let1 (comp obj e)
(lambda (objvar)
(begin1 (@impl pget
(-> (lexical objvar objvar))
(-> (const prop)))
(lambda (tmpvar)
(@impl pput
(-> (lexical objvar objvar))
(-> (const prop))
(-> (apply (-> (primitive '+))
(-> (lexical tmpvar tmpvar))
(-> (const 1))))))))))
((postinc (aref ,obj ,prop))
(let1 (comp obj e)
(lambda (objvar)
(let1 (comp prop e)
(lambda (propvar)
(begin1 (@impl pget
(-> (lexical objvar objvar))
(-> (lexical propvar propvar)))
(lambda (tmpvar)
(@impl pput
(-> (lexical objvar objvar))
(-> (lexical propvar propvar))
(-> (apply (-> (primitive '+))
(-> (lexical tmpvar tmpvar))
(-> (const 1))))))))))))
((postdec (ref ,foo))
(begin1 (comp `(ref ,foo) e)
(lambda (var)
(-> (set (lookup foo e)
(-> (apply (-> (primitive '-))
(-> (lexical var var))
(-> (const 1)))))))))
((postdec (pref ,obj ,prop))
(let1 (comp obj e)
(lambda (objvar)
(begin1 (@impl pget
(-> (lexical objvar objvar))
(-> (const prop)))
(lambda (tmpvar)
(@impl pput
(-> (lexical objvar objvar))
(-> (const prop))
(-> (apply (-> (primitive '-))
(-> (lexical tmpvar tmpvar))
(-> (const 1))))))))))
((postdec (aref ,obj ,prop))
(let1 (comp obj e)
(lambda (objvar)
(let1 (comp prop e)
(lambda (propvar)
(begin1 (@impl pget
(-> (lexical objvar objvar))
(-> (lexical propvar propvar)))
(lambda (tmpvar)
(@impl pput
(-> (lexical objvar objvar))
(-> (lexical propvar propvar))
(-> (inline
'- (-> (lexical tmpvar tmpvar))
(-> (const 1))))))))))))
((preinc (ref ,foo))
(let ((v (lookup foo e)))
(-> (begin
(-> (set! v
(-> (apply (-> (primitive '+))
v
(-> (const 1))))))
v))))
((preinc (pref ,obj ,prop))
(let1 (comp obj e)
(lambda (objvar)
(begin1 (-> (apply (-> (primitive '+))
(@impl pget
(-> (lexical objvar objvar))
(-> (const prop)))
(-> (const 1))))
(lambda (tmpvar)
(@impl pput (-> (lexical objvar objvar))
(-> (const prop))
(-> (lexical tmpvar tmpvar))))))))
((preinc (aref ,obj ,prop))
(let1 (comp obj e)
(lambda (objvar)
(let1 (comp prop e)
(lambda (propvar)
(begin1 (-> (apply (-> (primitive '+))
(@impl pget
(-> (lexical objvar objvar))
(-> (lexical propvar propvar)))
(-> (const 1))))
(lambda (tmpvar)
(@impl pput
(-> (lexical objvar objvar))
(-> (lexical propvar propvar))
(-> (lexical tmpvar tmpvar))))))))))
((predec (ref ,foo))
(let ((v (lookup foo e)))
(-> (begin
(-> (set! v
(-> (apply (-> (primitive '-))
v
(-> (const 1))))))
v))))
((predec (pref ,obj ,prop))
(let1 (comp obj e)
(lambda (objvar)
(begin1 (-> (apply (-> (primitive '-))
(@impl pget
(-> (lexical objvar objvar))
(-> (const prop)))
(-> (const 1))))
(lambda (tmpvar)
(@impl pput
(-> (lexical objvar objvar))
(-> (const prop))
(-> (lexical tmpvar tmpvar))))))))
((predec (aref ,obj ,prop))
(let1 (comp obj e)
(lambda (objvar)
(let1 (comp prop e)
(lambda (propvar)
(begin1 (-> (apply (-> (primitive '-))
(@impl pget
(-> (lexical objvar objvar))
(-> (lexical propvar propvar)))
(-> (const 1))))
(lambda (tmpvar)
(@impl pput
(-> (lexical objvar objvar))
(-> (lexical propvar propvar))
(-> (lexical tmpvar tmpvar))))))))))
((ref ,id)
(lookup id e))
((var . ,forms)
`(begin
,@(map (lambda (form)
(pmatch form
((,x ,y)
(-> (define x (comp y e))))
((,x)
(-> (define x (@implv *undefined*))))
(else (error "bad var form" form))))
forms)))
((begin)
(-> (void)))
((begin ,form)
(comp form e))
((begin . ,forms)
`(begin ,@(map (lambda (x) (comp x e)) forms)))
((lambda ,formals ,body)
(let ((syms (map (lambda (x)
(gensym (string-append (symbol->string x) " ")))
formals)))
`(lambda ()
(lambda-case
((() ,formals #f #f ,(map (lambda (x) (@implv *undefined*)) formals) ,syms)
,(with-return-prompt
(lambda ()
(comp-body e body formals syms))))))))
((call/this ,obj ,prop . ,args)
(@impl call/this*
obj
(-> (lambda '()
`(lambda-case
((() #f #f #f () ())
(apply ,(@impl pget obj prop) ,@args)))))))
((call (pref ,obj ,prop) ,args)
(comp `(call/this ,(comp obj e)
,(-> (const prop))
,@(map (lambda (x) (comp x e)) args))
e))
((call (aref ,obj ,prop) ,args)
(comp `(call/this ,(comp obj e)
,(comp prop e)
,@(map (lambda (x) (comp x e)) args))
e))
((call ,proc ,args)
`(apply ,(comp proc e)
,@(map (lambda (x) (comp x e)) args)))
((return ,expr)
(return (comp expr e)))
((array . ,args)
`(apply ,(@implv new-array)
,@(map (lambda (x) (comp x e)) args)))
((object . ,args)
`(apply ,(@implv new-object)
,@(map (lambda (x)
(pmatch x
((,prop ,val)
(-> (apply (-> (primitive 'cons))
(-> (const prop))
(comp val e))))
(else
(error "bad prop-val pair" x))))
args)))
((pref ,obj ,prop)
(@impl pget
(comp obj e)
(-> (const prop))))
((aref ,obj ,index)
(@impl pget
(comp obj e)
(comp index e)))
((= (ref ,name) ,val)
(let ((v (lookup name e)))
(-> (begin
(-> (set! v (comp val e)))
v))))
((= (pref ,obj ,prop) ,val)
(@impl pput
(comp obj e)
(-> (const prop))
(comp val e)))
((= (aref ,obj ,prop) ,val)
(@impl pput
(comp obj e)
(comp prop e)
(comp val e)))
((+= ,what ,val)
(comp `(= ,what (+ ,what ,val)) e))
((-= ,what ,val)
(comp `(= ,what (- ,what ,val)) e))
((/= ,what ,val)
(comp `(= ,what (/ ,what ,val)) e))
((*= ,what ,val)
(comp `(= ,what (* ,what ,val)) e))
((%= ,what ,val)
(comp `(= ,what (% ,what ,val)) e))
((>>= ,what ,val)
(comp `(= ,what (>> ,what ,val)) e))
((<<= ,what ,val)
(comp `(= ,what (<< ,what ,val)) e))
((>>>= ,what ,val)
(comp `(= ,what (>>> ,what ,val)) e))
((&= ,what ,val)
(comp `(= ,what (& ,what ,val)) e))
((bor= ,what ,val)
(comp `(= ,what (bor ,what ,val)) e))
((^= ,what ,val)
(comp `(= ,what (^ ,what ,val)) e))
((new ,what ,args)
(@impl new
(map (lambda (x) (comp x e))
(cons what args))))
((delete (pref ,obj ,prop))
(@impl pdel
(comp obj e)
(-> (const prop))))
((delete (aref ,obj ,prop))
(@impl pdel
(comp obj e)
(comp prop e)))
((void ,expr)
(-> (begin
(comp expr e)
(@implv *undefined*))))
((typeof ,expr)
(@impl typeof
(comp expr e)))
((do ,statement ,test)
(let ((%loop (gensym "%loop "))
(%continue (gensym "%continue ")))
(let ((e (econs '%loop %loop (econs '%continue %continue e))))
(-> (letrec '(%loop %continue) (list %loop %continue)
(list (-> (lambda '()
(-> (lambda-case
`((() #f #f #f () ())
,(-> (begin
(comp statement e)
(-> (apply (-> (lexical '%continue %continue)))))))))))
(-> (lambda '()
(-> (lambda-case
`((() #f #f #f () ())
,(-> (if (@impl ->boolean (comp test e))
(-> (apply (-> (lexical '%loop %loop))))
(@implv *undefined*)))))))))
(-> (apply (-> (lexical '%loop %loop)))))))))
((while ,test ,statement)
(let ((%continue (gensym "%continue ")))
(let ((e (econs '%continue %continue e)))
(-> (letrec '(%continue) (list %continue)
(list (-> (lambda '()
(-> (lambda-case
`((() #f #f #f () ())
,(-> (if (@impl ->boolean (comp test e))
(-> (begin (comp statement e)
(-> (apply (-> (lexical '%continue %continue))))))
(@implv *undefined*)))))))))
(-> (apply (-> (lexical '%continue %continue)))))))))
((for ,init ,test ,inc ,statement)
(let ((%continue (gensym "%continue ")))
(let ((e (econs '%continue %continue e)))
(-> (letrec '(%continue) (list %continue)
(list (-> (lambda '()
(-> (lambda-case
`((() #f #f #f () ())
,(-> (if (if test
(@impl ->boolean (comp test e))
(comp 'true e))
(-> (begin (comp statement e)
(comp (or inc '(begin)) e)
(-> (apply (-> (lexical '%continue %continue))))))
(@implv *undefined*)))))))))
(-> (begin (comp (or init '(begin)) e)
(-> (apply (-> (lexical '%continue %continue)))))))))))
((for-in ,var ,object ,statement)
(let ((%enum (gensym "%enum "))
(%continue (gensym "%continue ")))
(let ((e (econs '%enum %enum (econs '%continue %continue e))))
(-> (letrec '(%enum %continue) (list %enum %continue)
(list (@impl make-enumerator (comp object e))
(-> (lambda '()
(-> (lambda-case
`((() #f #f #f () ())
(-> (if (@impl ->boolean
(@impl pget
(-> (lexical '%enum %enum))
(-> (const 'length))))
(-> (begin
(comp `(= ,var (call/this ,(-> (lexical '%enum %enum))
,(-> (const 'pop))))
e)
(comp statement e)
(-> (apply (-> (lexical '%continue %continue))))))
(@implv *undefined*)))))))))
(-> (apply (-> (lexical '%continue %continue)))))))))
((block ,x)
(comp x e))
(else
(error "compilation not yet implemented:" x)))))
(define (comp-body e body formals formal-syms)
(define (process)
(let lp ((in body) (out '()) (rvars '()))
(pmatch in
(((var (,x) . ,morevars) . ,rest)
(lp `((var . ,morevars) . ,rest)
out
(if (or (memq x rvars) (memq x formals))
rvars
(cons x rvars))))
(((var (,x ,y) . ,morevars) . ,rest)
(lp `((var . ,morevars) . ,rest)
`((= (ref ,x) ,y) . ,out)
(if (or (memq x rvars) (memq x formals))
rvars
(cons x rvars))))
(((var) . ,rest)
(lp rest out rvars))
((,x . ,rest) (guard (and (pair? x) (eq? (car x) 'lambda)))
(lp rest
(cons x out)
rvars))
((,x . ,rest) (guard (pair? x))
(receive (sub-out rvars)
(lp x '() rvars)
(lp rest
(cons sub-out out)
rvars)))
((,x . ,rest)
(lp rest
(cons x out)
rvars))
(()
(values (reverse! out)
rvars)))))
(receive (out rvars)
(process)
(let* ((names (reverse rvars))
(syms (map (lambda (x)
(gensym (string-append (symbol->string x) " ")))
names))
(e (fold econs (fold econs e formals formal-syms) names syms)))
(-> (let names syms (map (lambda (x) (@implv *undefined*)) names)
(comp out e))))))