ikarus/src/ikarus.syntax.ss

2402 lines
95 KiB
Scheme

;;; FIXME: teach the compiler about (apply append ls) since I
;;; used it a zillion times in this file.
;;; other primitives that are usually apply'd include the
;;; arithmetic operations (+, =, min, max, ...).
;;; (apply (lambda ---) ls) is also common in this file.
(library (ikarus syntax)
(export identifier? syntax-dispatch environment environment?
eval generate-temporaries free-identifier=?
bound-identifier=? syntax-error datum->syntax
syntax->datum
eval-r6rs-top-level boot-library-expand eval-top-level)
(import
(r6rs)
(except (ikarus library-manager) installed-libraries)
(only (ikarus system $bootstrap) eval-core)
(chez modules)
(ikarus symbols)
(ikarus parameters)
(only (ikarus) error printf ormap andmap list* format
make-record-type void set-rtd-printer! type-descriptor)
(only (r6rs syntax-case) syntax-case syntax with-syntax)
(prefix (r6rs syntax-case) sys:))
(define who 'expander)
(define-syntax no-source
(lambda (x) #f))
(begin ;;; builders
(define-syntax build-application
(syntax-rules ()
((_ ae fun-exp arg-exps)
`(,fun-exp . ,arg-exps))))
(define-syntax build-conditional
(syntax-rules ()
((_ ae test-exp then-exp else-exp)
`(if ,test-exp ,then-exp ,else-exp))))
(define-syntax build-lexical-reference
(syntax-rules ()
((_ ae var) var)
((_ type ae var) var)))
(define-syntax build-lexical-assignment
(syntax-rules ()
((_ ae var exp) `(set! ,var ,exp))))
(define-syntax build-global-reference
(syntax-rules ()
[(_ ae var) `(top-level-value ',var)]))
(define-syntax build-global-assignment
(syntax-rules ()
[(_ ae var exp) `(#%set-top-level-value! ',var ,exp)]))
(define-syntax build-global-definition
(syntax-rules ()
[(_ ae var exp) (build-global-assignment ae var exp)]))
(define-syntax build-lambda
(syntax-rules ()
[(_ ae vars exp) `(case-lambda [,vars ,exp])]))
(define build-case-lambda
(lambda (ae vars* exp*)
`(case-lambda . ,(map list vars* exp*))))
(define build-let
(lambda (ae lhs* rhs* body)
`((case-lambda [,lhs* ,body]) . ,rhs*)))
(define-syntax build-primref
(syntax-rules ()
[(_ ae name) (build-primref ae 1 name)]
[(_ ae level name) `(|#primitive| ,name)]))
(define-syntax build-foreign-call
(syntax-rules ()
[(_ ae name arg*) `(foreign-call ,name . ,arg*)]))
(define-syntax build-data
(syntax-rules ()
((_ ae exp) `',exp)))
(define build-sequence
(lambda (ae exps)
(let loop ((exps exps))
(if (null? (cdr exps))
(car exps)
(if (equal? (car exps) '(#%void))
(loop (cdr exps))
`(begin ,@exps))))))
(define build-void
(lambda () '(#%void)))
(define build-letrec
(lambda (ae vars val-exps body-exp)
(if (null? vars) body-exp `(letrec ,(map list vars val-exps) ,body-exp))))
(define build-letrec*
(lambda (ae vars val-exps body-exp)
(if (null? vars) body-exp `(letrec* ,(map list vars val-exps) ,body-exp)))))
(define top-mark* '(top))
(define top-marked?
(lambda (m*) (memq 'top m*)))
(define gen-lexical
(lambda (sym)
(cond
[(symbol? sym)
(gensym (symbol->string sym))]
[(stx? sym) (gen-lexical (id->sym sym))]
[else (error 'gen-lexical "invalid arg ~s" sym)])))
(define (gen-global x) (gen-lexical x))
(define gen-label
(lambda (_) (gensym)))
(define-record rib (sym* mark** label* sealed/freq))
(define make-full-rib
(lambda (id* label*)
(make-rib (map id->sym id*) (map stx-mark* id*) label* #f)))
(define make-empty-rib
(lambda ()
(make-rib '() '() '() #f)))
(define extend-rib!
(lambda (rib id label)
(if (rib? rib)
(let ([sym (id->sym id)] [mark* (stx-mark* id)])
(when (rib-sealed/freq rib)
(error 'extend-rib! "rib ~s is sealed" rib))
(set-rib-sym*! rib (cons sym (rib-sym* rib)))
(set-rib-mark**! rib (cons mark* (rib-mark** rib)))
(set-rib-label*! rib (cons label (rib-label* rib))))
(error 'extend-rib! "~s is not a rib" rib))))
(define (extend-rib/check! rib id label)
(cond
[(rib? rib)
(when (rib-sealed/freq rib)
(error 'extend-rib/check! "rib ~s is sealed" rib))
(let ([sym (id->sym id)] [mark* (stx-mark* id)])
(let ([sym* (rib-sym* rib)])
(when (and (memq sym (rib-sym* rib))
(bound-id=? id
(stx sym mark* (list rib))))
(stx-error id "cannot redefine"))
(set-rib-sym*! rib (cons sym sym*))
(set-rib-mark**! rib (cons mark* (rib-mark** rib)))
(set-rib-label*! rib (cons label (rib-label* rib)))))]
[else (error 'extend-rib/check! "~s is not a rib" rib)]))
(module (make-stx stx? stx-expr stx-mark* stx-subst*)
(define-record stx (expr mark* subst*))
(set-rtd-printer! (type-descriptor stx)
(lambda (x p)
(display "#<syntax " p)
(display (stx->datum x) p)
(display ">" p))))
(define (seal-rib! rib)
(let ([sym* (rib-sym* rib)])
(unless (null? sym*)
;;; only seal if rib is not empty.
(let ([sym* (list->vector sym*)])
(set-rib-sym*! rib sym*)
(set-rib-mark**! rib
(list->vector (rib-mark** rib)))
(set-rib-label*! rib
(list->vector (rib-label* rib)))
(set-rib-sealed/freq! rib
(make-vector (vector-length sym*) 0))))))
(define (unseal-rib! rib)
(when (rib-sealed/freq rib)
(set-rib-sealed/freq! rib #f)
(set-rib-sym*! rib (vector->list (rib-sym* rib)))
(set-rib-mark**! rib (vector->list (rib-mark** rib)))
(set-rib-label*! rib (vector->list (rib-label* rib)))))
(define datum->stx
(lambda (id datum)
(make-stx datum (stx-mark* id) (stx-subst* id))))
(define join-wraps
(lambda (m1* s1* e)
(define cancel
(lambda (ls1 ls2)
(let f ((x (car ls1)) (ls1 (cdr ls1)))
(if (null? ls1)
(cdr ls2)
(cons x (f (car ls1) (cdr ls1)))))))
(let ((m2* (stx-mark* e)) (s2* (stx-subst* e)))
(if (and (not (null? m1*))
(not (null? m2*))
(eq? (car m2*) anti-mark))
; cancel mark, anti-mark, and corresponding shifts
(values (cancel m1* m2*) (cancel s1* s2*))
(values (append m1* m2*) (append s1* s2*))))))
(define stx
(lambda (e m* s*)
(if (stx? e)
(let-values ([(m* s*) (join-wraps m* s* e)])
(make-stx (stx-expr e) m* s*))
(make-stx e m* s*))))
(define add-subst
(lambda (subst e)
(if subst
(stx e '() (list subst))
e)))
(define gen-mark
(lambda () (string #\m)))
(define add-mark
(lambda (m e)
(stx e (list m) '(shift))))
(define anti-mark #f)
(define syntax-kind?
(lambda (x p?)
(if (stx? x)
(syntax-kind? (stx-expr x) p?)
(p? x))))
(define syntax-vector->list
(lambda (x)
(cond
[(stx? x)
(let ([ls (syntax-vector->list (stx-expr x))]
[m* (stx-mark* x)] [s* (stx-subst* x)])
(map (lambda (x) (stx x m* s*)) ls))]
[(vector? x) (vector->list x)]
[else (error 'syntax-vector->list "not a syntax vector ~s" x)])))
(define syntax-pair?
(lambda (x) (syntax-kind? x pair?)))
(define syntax-vector?
(lambda (x) (syntax-kind? x vector?)))
(define syntax-null?
(lambda (x) (syntax-kind? x null?)))
(define syntax-list?
(lambda (x)
(or (syntax-null? x)
(and (syntax-pair? x) (syntax-list? (syntax-cdr x))))))
(define syntax-car
(lambda (x)
(if (stx? x)
(stx (syntax-car (stx-expr x)) (stx-mark* x) (stx-subst* x))
(if (pair? x)
(car x)
(error 'syntax-car "~s is not a pair" x)))))
(define syntax->list
(lambda (x)
(if (syntax-pair? x)
(cons (syntax-car x) (syntax->list (syntax-cdr x)))
(if (syntax-null? x)
'()
(error 'syntax->list "invalid ~s" x)))))
(define syntax-cdr
(lambda (x)
(if (stx? x)
(stx (syntax-cdr (stx-expr x)) (stx-mark* x) (stx-subst* x))
(if (pair? x)
(cdr x)
(error 'syntax-cdr "~s is not a pair" x)))))
(define id?
(lambda (x) (syntax-kind? x symbol?)))
(define id->sym
(lambda (x)
(if (stx? x)
(id->sym (stx-expr x))
(if (symbol? x)
x
(error 'id->sym "~s is not an id" x)))))
(define same-marks?
(lambda (x y)
(or (eq? x y)
(and (pair? x) (pair? y)
(eq? (car x) (car y))
(same-marks? (cdr x) (cdr y))))))
(define bound-id=?
(lambda (x y)
(and (eq? (id->sym x) (id->sym y))
(same-marks? (stx-mark* x) (stx-mark* y)))))
(define free-id=?
(lambda (i j)
(let ((t0 (id->label i)) (t1 (id->label j)))
(if (or t0 t1)
(eq? t0 t1)
(eq? (id->sym i) (id->sym j))))))
(define valid-bound-ids?
(lambda (id*)
(and (andmap id? id*)
(distinct-bound-ids? id*))))
(define distinct-bound-ids?
(lambda (id*)
(or (null? id*)
(and (not (bound-id-member? (car id*) (cdr id*)))
(distinct-bound-ids? (cdr id*))))))
(define bound-id-member?
(lambda (id id*)
(and (pair? id*)
(or (bound-id=? id (car id*))
(bound-id-member? id (cdr id*))))))
(define self-evaluating?
(lambda (x)
(or (number? x) (string? x) (char? x) (boolean? x))))
(define stx->datum
(lambda (x)
(strip x '())))
(define extend-env
(lambda (lab b r)
(cons (cons lab b) r)))
(define extend-env*
(lambda (lab* b* r)
(append (map cons lab* b*) r)))
(define cons-id
(lambda (kwd kwd*)
(if (id? kwd)
(cons kwd kwd*)
kwd*)))
(define strip
(lambda (x m*)
(if (top-marked? m*)
x
(let f ([x x])
(cond
[(stx? x) (strip (stx-expr x) (stx-mark* x))]
[(pair? x)
(let ([a (f (car x))] [d (f (cdr x))])
(if (and (eq? a (car x)) (eq? d (cdr x)))
x
(cons a d)))]
[(vector? x)
(let ([old (vector->list x)])
(let ([new (map f old)])
(if (andmap eq? old new)
x
(list->vector new))))]
[else x])))))
(define (increment-rib-frequency! rib idx)
(let ([freq* (rib-sealed/freq rib)])
(let ([freq (vector-ref freq* idx)])
(let ([i
(let f ([i idx])
(cond
[(zero? i) 0]
[else
(let ([j (- i 1)])
(cond
[(= freq (vector-ref freq* j)) (f j)]
[else i]))]))])
(vector-set! freq* i (+ freq 1))
(unless (= i idx)
(let ([sym* (rib-sym* rib)]
[mark** (rib-mark** rib)]
[label* (rib-label* rib)])
(let ([sym (vector-ref sym* idx)])
(vector-set! sym* idx (vector-ref sym* i))
(vector-set! sym* i sym))
(let ([mark* (vector-ref mark** idx)])
(vector-set! mark** idx (vector-ref mark** i))
(vector-set! mark** i mark*))
(let ([label (vector-ref label* idx)])
(vector-set! label* idx (vector-ref label* i))
(vector-set! label* i label))))))))
(define interaction-library
(make-parameter #f))
(define id->label
(lambda (id)
(let ([sym (id->sym id)])
(let search ([subst* (stx-subst* id)] [mark* (stx-mark* id)])
(cond
[(null? subst*)
(cond
[(interaction-library) =>
(lambda (lib)
(cond
[(assq sym (library-subst lib)) => cdr]
[else
(let ([subst (library-subst
(find-library-by-name '(ikarus)))])
(cond
[(assq sym subst) =>
(lambda (sym/lab)
(let ([label (cdr sym/lab)])
(extend-library-subst! lib sym label)
label))]
[else
(let ([label (gen-label sym)])
(extend-library-subst! lib sym label)
(extend-library-env! lib label
(cons 'global (cons lib (gen-global sym))))
label)]))]))]
[else #f])]
[(eq? (car subst*) 'shift)
(search (cdr subst*) (cdr mark*))]
[else
(let ([rib (car subst*)])
(cond
[(rib-sealed/freq rib)
(let ([sym* (rib-sym* rib)])
(let f ([i 0] [n (- (vector-length sym*) 1)])
(cond
[(and (eq? (vector-ref sym* i) sym)
(same-marks? mark*
(vector-ref (rib-mark** rib) i)))
(let ([label (vector-ref (rib-label* rib) i)])
(increment-rib-frequency! rib i)
label)]
[(= i n) (search (cdr subst*) mark*)]
[else (f (+ i 1) n)])))]
[else
(let f ([sym* (rib-sym* rib)]
[mark** (rib-mark** rib)]
[label* (rib-label* rib)])
(cond
[(null? sym*) (search (cdr subst*) mark*)]
[(and (eq? (car sym*) sym)
(same-marks? (car mark**) mark*))
(car label*)]
[else (f (cdr sym*) (cdr mark**) (cdr label*))]))]))])))))
(define label->binding
(lambda (x r)
(cond
[(imported-label->binding x)]
[(assq x r) => cdr]
[else (cons 'displaced-lexical #f)])))
(define make-binding cons)
(define binding-type car)
(define binding-value cdr)
(define local-binding-value cadr)
(define local-macro-src cddr)
(define syntax-type
(lambda (e r)
(cond
[(id? e)
(let ([id e])
(let* ([label (id->label id)]
[b (label->binding label r)]
[type (binding-type b)])
(unless label
(stx-error e "unbound identifier"))
(case type
[(lexical core-prim macro global local-macro
global-macro displaced-lexical syntax import
$module)
(values type (binding-value b) id)]
[else (values 'other #f #f)])))]
[(syntax-pair? e)
(let ([id (syntax-car e)])
(if (id? id)
(let* ([label (id->label id)]
[b (label->binding label r)]
[type (binding-type b)])
(case type
[(define define-syntax core-macro begin macro
local-macro global-macro module set!
let-syntax letrec-syntax import)
(values type (binding-value b) id)]
[else
(values 'call #f #f)]))
(values 'call #f #f)))]
[else (let ([d (strip e '())])
(if (self-evaluating? d)
(values 'constant d #f)
(values 'other #f #f)))])))
(define-syntax stx-error
(lambda (x)
(syntax-case x ()
[(_ stx) #'(error #f "invalid syntax ~s" (strip stx '()))]
[(_ stx msg) #'(error #f "~a: ~s" msg (strip stx '()))])))
(define sanitize-binding
(lambda (x src)
(cond
[(procedure? x) (list* 'local-macro x src)]
[(and (pair? x) (eq? (car x) 'macro!) (procedure? (cdr x)))
(list* 'local-macro! (cdr x) src)]
[(and (pair? x) (eq? (car x) '$rtd)) x]
[else (error 'expand "invalid transformer ~s" x)])))
(define make-eval-transformer
(lambda (x)
(sanitize-binding (eval-core x) x)))
(define-syntax syntax-match
(lambda (ctx)
(define dots?
(lambda (x)
(and (sys:identifier? x)
(sys:free-identifier=? x #'(... ...)))))
(define free-identifier-member?
(lambda (x ls)
(and (ormap (lambda (y) (sys:free-identifier=? x y)) ls) #t)))
(define (parse-clause lits cls)
(define (parse-pat pat)
(syntax-case pat ()
[id (sys:identifier? #'id)
(cond
[(free-identifier-member? #'id lits)
(values '()
#'(lambda (x)
(and (id? x)
(free-id=? x (scheme-stx 'id))
'())))]
[(sys:free-identifier=? #'id #'_)
(values '() #'(lambda (x) '()))]
[else
(values (list #'id) #'(lambda (x) (list x)))])]
[(pat dots) (dots? #'dots)
(let-values ([(pvars decon) (parse-pat #'pat)])
(with-syntax ([(v* ...) pvars] [decon decon])
(values pvars
#'(letrec ([f (lambda (x)
(cond
[(syntax-pair? x)
(let ([cars/f (decon (syntax-car x))])
(and cars/f
(let ([cdrs/f (f (syntax-cdr x))])
(and cdrs/f
(map cons cars/f cdrs/f)))))]
[(syntax-null? x)
(list (begin 'v* '()) ...)]
[else #f]))])
f))))]
[(pat dots . last) (dots? #'dots)
(let-values ([(p1 d1) (parse-pat #'pat)]
[(p2 d2) (parse-pat #'last)])
(with-syntax ([(v* ...) (append p1 p2)]
[(v1* ...) p1]
[(v2* ...) p2]
[d1 d1] [d2 d2])
(values (append p1 p2)
#'(letrec ([f (lambda (x)
(cond
[(syntax-pair? x)
(let ([cars/f (d1 (syntax-car x))])
(and cars/f
(let ([d/f (f (syntax-cdr x))])
(and d/f
(cons (map cons cars/f (car d/f))
(cdr d/f))))))]
[else
(let ([d (d2 x)])
(and d
(cons (list (begin 'v1* '()) ...)
d)))]))])
(lambda (x)
(let ([x (f x)])
(and x (append (car x) (cdr x)))))))))]
[(pat1 . pat2)
(let-values ([(p1 d1) (parse-pat #'pat1)]
[(p2 d2) (parse-pat #'pat2)])
(with-syntax ([d1 d1] [d2 d2])
(values (append p1 p2)
#'(lambda (x)
(and (syntax-pair? x)
(let ([q (d1 (syntax-car x))])
(and q
(let ([r (d2 (syntax-cdr x))])
(and r (append q r))))))))))]
[#(pats ...)
(let-values ([(pvars d) (parse-pat #'(pats ...))])
(with-syntax ([d d])
(values pvars
#'(lambda (x)
(and (syntax-vector? x)
(d (syntax-vector->list x)))))))]
[datum
(values '()
#'(lambda (x)
(and (equal? (strip x '()) 'datum) '())))]))
(syntax-case cls ()
[(pat body)
(let-values ([(pvars decon) (parse-pat #'pat)])
(with-syntax ([(v* ...) pvars])
(values decon
#'(lambda (v* ...) #t)
#'(lambda (v* ...) body))))]
[(pat guard body)
(let-values ([(pvars decon) (parse-pat #'pat)])
(with-syntax ([(v* ...) pvars])
(values decon
#'(lambda (v* ...) guard)
#'(lambda (v* ...) body))))]))
(syntax-case ctx ()
[(_ expr (lits ...)) (andmap sys:identifier? #'(lits ...))
#'(stx-error expr "invalid syntax")]
[(_ expr (lits ...) cls cls* ...) (andmap sys:identifier? #'(lits ...))
(let-values ([(decon guard body)
(parse-clause #'(lits ...) #'cls)])
(with-syntax ([decon decon] [guard guard] [body body])
#'(let ([t expr])
(let ([ls/false (decon t)])
(if (and ls/false (apply guard ls/false))
(apply body ls/false)
(syntax-match t (lits ...) cls* ...))))))])))
(define parse-define
(lambda (x)
(syntax-match x ()
[(_ (id . fmls) b b* ...) (id? id)
(values id (cons 'defun (cons fmls (cons b b*))))]
[(_ id val) (id? id)
(values id (cons 'expr val))])))
(define parse-define-syntax
(lambda (x)
(syntax-match x ()
[(_ id val) (id? id) (values id val)])))
(define scheme-stx
(lambda (sym)
(let ([subst
(library-subst
(find-library-by-name '(ikarus system $all)))])
(cond
[(assq sym subst) =>
(lambda (x)
(let ([name (car x)] [label (cdr x)])
(add-subst
(make-rib (list name) (list top-mark*) (list label) #f)
(stx sym top-mark* '()))))]
[else (stx sym top-mark* '())]))))
;;; macros
(define add-lexical
(lambda (lab lex r)
(cons (list* lab 'lexical lex) r)))
;;;
(define add-lexicals
(lambda (lab* lex* r)
(cond
[(null? lab*) r]
[else
(add-lexicals (cdr lab*) (cdr lex*)
(add-lexical (car lab*) (car lex*) r))])))
;;;
(define let-values-transformer ;;; go away
(lambda (e r mr)
(syntax-match e ()
[(_ ([(fml** ...) rhs*] ...) b b* ...)
(let ([rhs* (chi-expr* rhs* r mr)])
(let ([lex** (map (lambda (ls) (map gen-lexical ls)) fml**)]
[lab** (map (lambda (ls) (map gen-label ls)) fml**)])
(let ([fml* (apply append fml**)]
[lab* (apply append lab**)]
[lex* (apply append lex**)])
(let f ([lex** lex**] [rhs* rhs*])
(cond
[(null? lex**)
(chi-internal
(add-subst
(make-full-rib fml* lab*)
(cons b b*))
(add-lexicals lab* lex* r)
mr)]
[else
(build-application no-source
(build-primref no-source 'call-with-values)
(list
(build-lambda no-source '() (car rhs*))
(build-lambda no-source (car lex**)
(f (cdr lex**) (cdr rhs*)))))])))))])))
(module (letrec-transformer letrec*-transformer)
(define helper
(lambda (e r mr letrec?)
(syntax-match e ()
[(_ ([lhs* rhs*] ...) b b* ...)
(if (not (valid-bound-ids? lhs*))
(stx-error e "duplicate identifiers")
(let ([lex* (map gen-lexical lhs*)]
[lab* (map gen-label lhs*)])
(let ([rib (make-full-rib lhs* lab*)]
[r (add-lexicals lab* lex* r)])
(let ([body (chi-internal
(add-subst rib (cons b b*))
r mr)]
[rhs* (chi-expr*
(map (lambda (x)
(add-subst rib x))
rhs*)
r mr)])
((if letrec? build-letrec build-letrec*)
no-source lex* rhs* body)))))])))
(define letrec-transformer
(lambda (e r mr) (helper e r mr #t)))
(define letrec*-transformer
(lambda (e r mr) (helper e r mr #f))))
(define type-descriptor-transformer
(lambda (e r mr)
(syntax-match e ()
[(_ id) (id? id)
(let* ([lab (id->label id)]
[b (label->binding lab r)]
[type (binding-type b)])
(unless lab (stx-error e "unbound identifier"))
(case type
[($rtd)
(build-data no-source (binding-value b))]
[else (stx-error e "invalid type")]))])))
(define when-transformer ;;; go away
(lambda (e r mr)
(syntax-match e ()
[(_ test e e* ...)
(build-conditional no-source
(chi-expr test r mr)
(build-sequence no-source
(chi-expr* (cons e e*) r mr))
(build-void))])))
(define unless-transformer ;;; go away
(lambda (e r mr)
(syntax-match e ()
[(_ test e e* ...)
(build-conditional no-source
(chi-expr test r mr)
(build-void)
(build-sequence no-source
(chi-expr* (cons e e*) r mr)))])))
(define if-transformer
(lambda (e r mr)
(syntax-match e ()
[(_ e0 e1 e2)
(build-conditional no-source
(chi-expr e0 r mr)
(chi-expr e1 r mr)
(chi-expr e2 r mr))]
[(_ e0 e1)
(build-conditional no-source
(chi-expr e0 r mr)
(chi-expr e1 r mr)
(build-void))])))
(define case-transformer ;;; go away
(lambda (e r mr)
(define build-one
(lambda (t cls rest)
(syntax-match cls ()
[((d* ...) e e* ...)
(build-conditional no-source
(build-application no-source
(build-primref no-source 'memv)
(list t (build-data no-source (strip d* '()))))
(build-sequence no-source
(chi-expr* (cons e e*) r mr))
rest)]
[else (stx-error e)])))
(define build-last
(lambda (t cls)
(syntax-match cls ()
[((d* ...) e e* ...)
(build-one t cls (build-void))]
[(else-kwd x x* ...)
(if (and (id? else-kwd)
(free-id=? else-kwd (scheme-stx 'else)))
(build-sequence no-source
(chi-expr* (cons x x*) r mr))
(stx-error e))]
[else (stx-error e)])))
(syntax-match e ()
[(_ expr)
(build-sequence no-source
(list (chi-expr expr r mr) (build-void)))]
[(_ expr cls cls* ...)
(let ([t (gen-lexical 't)])
(build-let no-source
(list t) (list (chi-expr expr r mr))
(let f ([cls cls] [cls* cls*])
(cond
[(null? cls*) (build-last t cls)]
[else
(build-one t cls
(f (car cls*) (cdr cls*)))]))))])))
(define quote-transformer
(lambda (e r mr)
(syntax-match e ()
[(_ datum) (build-data no-source (strip datum '()))])))
(define case-lambda-transformer
(lambda (e r mr)
(syntax-match e ()
[(_ [fmls* b* b** ...] ...)
(let-values ([(fmls* body*)
(chi-lambda-clause* fmls*
(map cons b* b**) r mr)])
(build-case-lambda no-source fmls* body*))])))
(define lambda-transformer
(lambda (e r mr)
(syntax-match e ()
[(_ fmls b b* ...)
(let-values ([(fmls body)
(chi-lambda-clause fmls
(cons b b*) r mr)])
(build-lambda no-source fmls body))])))
(define bless
(lambda (x)
(stx
(let f ([x x])
(cond
[(pair? x) (cons (f (car x)) (f (cdr x)))]
[(symbol? x) (scheme-stx x)]
[else x]))
'() '())))
(define with-syntax-macro
(lambda (e)
(syntax-match e ()
[(_ ([fml* expr*] ...) b b* ...)
(bless
`(syntax-case (list . ,expr*) ()
[,fml* (begin ,b . ,b*)]))])))
(define let-macro
(lambda (stx)
(syntax-match stx ()
[(_ ([lhs* rhs*] ...) b b* ...)
(if (valid-bound-ids? lhs*)
(bless `((lambda ,lhs* ,b . ,b*) . ,rhs*))
(stx-error stx "duplicate bindings"))]
[(_ f ([lhs* rhs*] ...) b b* ...) (id? f)
(if (valid-bound-ids? lhs*)
(bless `(letrec ([,f (lambda ,lhs* ,b . ,b*)])
(,f . ,rhs*)))
(stx-error stx "invalid syntax"))])))
(define identifier-syntax-macro
(lambda (stx)
(syntax-match stx ()
[(_ expr)
(bless `(lambda (x)
(syntax-case x ()
[id (identifier? #'id) #',expr]
[(id e* ...) (identifier? #'id)
(cons #',expr #'(e* ...))])))])))
(define do-macro
(lambda (stx)
(define bind
(lambda (x)
(syntax-match x ()
[(x init) `(,x ,init ,x)]
[(x init step) `(,x ,init ,step)]
[_ (stx-error stx "invalid binding")])))
(syntax-match stx ()
[(_ (binding* ...)
(test expr* ...)
command* ...)
(syntax-match (map bind binding*) ()
[([x* init* step*] ...)
(if (valid-bound-ids? x*)
(bless
`(letrec ([loop
(lambda ,x*
(if ,test
(begin (void) ,@expr*)
(begin
,@command*
(loop ,@step*))))])
(loop ,@init*)))
(stx-error stx "duplicate bindings"))])])))
(define let*-macro
(lambda (stx)
(syntax-match stx ()
[(_ ([lhs* rhs*] ...) b b* ...) (andmap id? lhs*)
(bless
(let f ([x* (map list lhs* rhs*)])
(cond
[(null? x*) `(let () ,b . ,b*)]
[else `(let (,(car x*)) ,(f (cdr x*)))])))])))
(define or-macro
(lambda (stx)
(syntax-match stx ()
[(_) #f]
[(_ e e* ...)
(bless
(let f ([e e] [e* e*])
(cond
[(null? e*) `(begin #f ,e)]
[else
`(let ([t ,e])
(if t t ,(f (car e*) (cdr e*))))])))])))
(define and-macro
(lambda (stx)
(syntax-match stx ()
[(_) #t]
[(_ e e* ...)
(bless
(let f ([e e] [e* e*])
(cond
[(null? e*) `(begin #f ,e)]
[else `(if ,e ,(f (car e*) (cdr e*)) #f)])))])))
(define cond-macro
(lambda (stx)
(syntax-match stx ()
[(_ cls cls* ...)
(bless
(let f ([cls cls] [cls* cls*])
(cond
[(null? cls*)
(syntax-match cls (else =>)
[(else e e* ...) `(begin ,e . ,e*)]
[(e => p) `(let ([t ,e]) (if t (,p t) (void)))]
[(e) `(or ,e (void))]
[(e e* ...) `(if ,e (begin . ,e*) (void))]
[_ (stx-error stx "invalid last clause")])]
[else
(syntax-match cls (else =>)
[(else e e* ...) (stx-error stx "incorrect position of keyword else")]
[(e => p) `(let ([t ,e]) (if t (,p t) ,(f (car cls*) (cdr cls*))))]
[(e) `(or ,e ,(f (car cls*) (cdr cls*)))]
[(e e* ...) `(if ,e (begin . ,e*) ,(f (car cls*) (cdr cls*)))]
[_ (stx-error stx "invalid last clause")])])))])))
(define include-macro
(lambda (e)
(syntax-match e ()
[(id filename)
(let ([filename (stx->datum filename)])
(unless (string? filename) (stx-error e))
(with-input-from-file filename
(lambda ()
(let f ([ls '()])
(let ([x (read)])
(cond
[(eof-object? x)
(cons (bless 'begin)
(datum->stx id (reverse ls)))]
[else (f (cons x ls))]))))))])))
(define syntax-rules-macro
(lambda (e)
(syntax-match e ()
[(_ (lits ...)
[pat* tmp*] ...)
(begin
(unless (andmap
(lambda (x)
(and (id? x)
(not (free-id=? x (scheme-stx '...)))
(not (free-id=? x (scheme-stx '_)))))
lits)
(stx-error e "invalid literals"))
(bless `(lambda (x)
(syntax-case x ,lits
,@(map (lambda (pat tmp)
`[,pat (syntax ,tmp)])
pat* tmp*)))))])))
(define quasiquote-macro
(let ()
(define-syntax app
(syntax-rules (quote)
[(_ 'x arg* ...)
(list (scheme-stx 'x) arg* ...)]))
(define-syntax app*
(syntax-rules (quote)
[(_ 'x arg* ... last)
(list* (scheme-stx 'x) arg* ... last)]))
(define quasilist*
(lambda (x y)
(let f ((x x))
(if (null? x) y (quasicons (car x) (f (cdr x)))))))
(define quasicons
(lambda (x y)
(syntax-match y (quote list)
[(quote dy)
(syntax-match x (quote)
[(quote dx) (app 'quote (cons dx dy))]
[_
(syntax-match dy ()
[() (app 'list x)]
[_ (app 'cons x y)])])]
[(list stuff ...)
(app* 'list x stuff)]
[_ (app 'cons x y)])))
(define quasiappend
(lambda (x y)
(let ([ls (let f ((x x))
(if (null? x)
(syntax-match y (quote)
[(quote ()) '()]
[_ (list y)])
(syntax-match (car x) (quote)
[(quote ()) (f (cdr x))]
[_ (cons (car x) (f (cdr x)))])))])
(cond
[(null? ls) (app 'quote '())]
[(null? (cdr ls)) (car ls)]
[else (app* 'append ls)]))))
(define quasivector
(lambda (x)
(let ((pat-x x))
(syntax-match pat-x (quote)
[(quote (x* ...)) (app 'quote (list->vector x*))]
[_ (let f ((x x) (k (lambda (ls) (app* 'vector ls))))
(syntax-match x (quote list cons)
[(quote (x* ...))
(k (map (lambda (x) (app 'quote x)) x*))]
[(list x* ...)
(k x*)]
[(cons x y)
(f y (lambda (ls) (k (cons x ls))))]
[_ (app 'list->vector pat-x)]))]))))
(define vquasi
(lambda (p lev)
(syntax-match p ()
[(p . q)
(syntax-match p (unquote unquote-splicing)
[(unquote p ...)
(if (= lev 0)
(quasilist* p (vquasi q lev))
(quasicons
(quasicons (app 'quote 'unquote)
(quasi p (- lev 1)))
(vquasi q lev)))]
[(unquote-splicing p ...)
(if (= lev 0)
(quasiappend p (vquasi q lev))
(quasicons
(quasicons
(app 'quote 'unquote-splicing)
(quasi p (- lev 1)))
(vquasi q lev)))]
[p (quasicons (quasi p lev) (vquasi q lev))])]
[() (app 'quote '())])))
(define quasi
(lambda (p lev)
(syntax-match p (unquote unquote-splicing quasiquote)
[(unquote p)
(if (= lev 0)
p
(quasicons (app 'quote 'unquote) (quasi (list p) (- lev 1))))]
[((unquote p ...) . q)
(if (= lev 0)
(quasilist* p (quasi q lev))
(quasicons
(quasicons (app 'quote 'unquote) (quasi p (- lev 1)))
(quasi q lev)))]
[((unquote-splicing p ...) . q)
(if (= lev 0)
(quasiappend p (quasi q lev))
(quasicons
(quasicons
(app 'quote 'unquote-splicing)
(quasi p (- lev 1)))
(quasi q lev)))]
[(quasiquote p)
(quasicons (app 'quote 'quasiquote) (quasi (list p) (+ lev 1)))]
[(p . q) (quasicons (quasi p lev) (quasi q lev))]
[#(x ...) (quasivector (vquasi x lev))]
[p (app 'quote p)])))
(lambda (x)
(syntax-match x ()
[(_ e) (quasi e 0)]))))
(define define-record-macro
(lambda (e)
(define enumerate
(lambda (ls)
(let f ([i 0] [ls ls])
(cond
[(null? ls) '()]
[else (cons i (f (+ i 1) (cdr ls)))]))))
(define mkid
(lambda (id str)
(datum->stx id (string->symbol str))))
(syntax-match e ()
[(_ name (field* ...))
(let* ([namestr (symbol->string (id->sym name))]
[fields (map id->sym field*)]
[fieldstr* (map symbol->string fields)]
[rtd (datum->stx name (make-record-type namestr fields))]
[constr (mkid name (format "make-~a" namestr))]
[pred (mkid name (format "~a?" namestr))]
[i* (enumerate field*)]
[getters
(map (lambda (x)
(mkid name (format "~a-~a" namestr x)))
fieldstr*)]
[setters
(map (lambda (x)
(mkid name (format "set-~a-~a!" namestr x)))
fieldstr*)])
(bless
`(begin
(define-syntax ,name (cons '$rtd ',rtd))
(define ,constr
(lambda ,field*
($record ',rtd ,@field*)))
(define ,pred
(lambda (x) ($record/rtd? x ',rtd)))
,@(map (lambda (getter i)
`(define ,getter
(lambda (x)
(if ($record/rtd? x ',rtd)
($record-ref x ,i)
(error ',getter
"~s is not a record of type ~s"
x ',rtd)))))
getters i*)
,@(map (lambda (setter i)
`(define ,setter
(lambda (x v)
(if ($record/rtd? x ',rtd)
($record-set! x ,i v)
(error ',setter
"~s is not a record of type ~s"
x ',rtd)))))
setters i*))))])))
(define parameterize-transformer ;;; go away
(lambda (e r mr)
(syntax-match e ()
[(_ () b b* ...)
(chi-internal (cons b b*) r mr)]
[(_ ([olhs* orhs*] ...) b b* ...)
(let ([lhs* (map (lambda (x) (gen-lexical 'lhs)) olhs*)]
[rhs* (map (lambda (x) (gen-lexical 'rhs)) olhs*)]
[t* (map (lambda (x) (gen-lexical 't)) olhs*)]
[swap (gen-lexical 'swap)])
(build-let no-source
(append lhs* rhs*)
(append (chi-expr* olhs* r mr) (chi-expr* orhs* r mr))
(build-let no-source
(list swap)
(list (build-lambda no-source '()
(build-sequence no-source
(map (lambda (t lhs rhs)
(build-let no-source
(list t)
(list (build-application no-source
(build-lexical-reference no-source lhs)
'()))
(build-sequence no-source
(list (build-application no-source
(build-lexical-reference no-source lhs)
(list (build-lexical-reference no-source rhs)))
(build-lexical-assignment no-source rhs
(build-lexical-reference no-source t))))))
t* lhs* rhs*))))
(build-application no-source
(build-primref no-source 'dynamic-wind)
(list (build-lexical-reference no-source swap)
(build-lambda no-source '()
(chi-internal (cons b b*) r mr))
(build-lexical-reference no-source swap))))))])))
(define foreign-call-transformer
(lambda (e r mr)
(syntax-match e ()
[(_ name arg* ...)
(build-foreign-call no-source
(chi-expr name r mr)
(chi-expr* arg* r mr))])))
;; p in pattern: matches:
;; () empty list
;; _ anything (no binding created)
;; any anything
;; (p1 . p2) pair
;; #(free-id <key>) <key> with free-identifier=?
;; each-any any proper list
;; #(each p) (p*)
;; #(each+ p1 (p2_1 ... p2_n) p3) (p1* (p2_n ... p2_1) . p3)
;; #(vector p) #(x ...) if p matches (x ...)
;; #(atom <object>) <object> with "equal?"
(define convert-pattern
; returns syntax-dispatch pattern & ids
(lambda (pattern keys)
(define cvt*
(lambda (p* n ids)
(if (null? p*)
(values '() ids)
(let-values (((y ids) (cvt* (cdr p*) n ids)))
(let-values (((x ids) (cvt (car p*) n ids)))
(values (cons x y) ids))))))
(define cvt
(lambda (p n ids)
(syntax-match p ()
[id (id? id)
(cond
[(bound-id-member? p keys)
(values `#(free-id ,p) ids)]
[(free-id=? p (scheme-stx '_))
(values '_ ids)]
[else (values 'any (cons (cons p n) ids))])]
[(p dots) (ellipsis? dots)
(let-values ([(p ids) (cvt p (+ n 1) ids)])
(values
(if (eq? p 'any) 'each-any `#(each ,p))
ids))]
[(x dots ys ... . z) (ellipsis? dots)
(let-values ([(z ids) (cvt z n ids)])
(let-values ([(ys ids) (cvt* ys n ids)])
(let-values ([(x ids) (cvt x (+ n 1) ids)])
(values `#(each+ ,x ,(reverse ys) ,z) ids))))]
[(x . y)
(let-values ([(y ids) (cvt y n ids)])
(let-values ([(x ids) (cvt x n ids)])
(values (cons x y) ids)))]
[() (values '() ids)]
[#(p ...)
(let-values ([(p ids) (cvt p n ids)])
(values `#(vector ,p) ids))]
[datum
(values `#(atom ,(strip datum '())) ids)])))
(cvt pattern 0 '())))
(define syntax-dispatch
(lambda (e p)
(define match-each
(lambda (e p m* s*)
(cond
((pair? e)
(let ((first (match (car e) p m* s* '())))
(and first
(let ((rest (match-each (cdr e) p m* s*)))
(and rest (cons first rest))))))
((null? e) '())
((stx? e)
(let-values (((m* s*) (join-wraps m* s* e)))
(match-each (stx-expr e) p m* s*)))
(else #f))))
(define match-each+
(lambda (e x-pat y-pat z-pat m* s* r)
(let f ((e e) (m* m*) (s* s*))
(cond
((pair? e)
(let-values (((xr* y-pat r) (f (cdr e) m* s*)))
(if r
(if (null? y-pat)
(let ((xr (match (car e) x-pat m* s* '())))
(if xr
(values (cons xr xr*) y-pat r)
(values #f #f #f)))
(values
'()
(cdr y-pat)
(match (car e) (car y-pat) m* s* r)))
(values #f #f #f))))
((stx? e)
(let-values (((m* s*) (join-wraps m* s* e)))
(f (stx-expr e) m* s*)))
(else (values '() y-pat (match e z-pat m* s* r)))))))
(define match-each-any
(lambda (e m* s*)
(cond
((pair? e)
(let ((l (match-each-any (cdr e) m* s*)))
(and l (cons (stx (car e) m* s*) l))))
((null? e) '())
((stx? e)
(let-values (((m* s*) (join-wraps m* s* e)))
(match-each-any (stx-expr e) m* s*)))
(else #f))))
(define match-empty
(lambda (p r)
(cond
((null? p) r)
((eq? p '_) r)
((eq? p 'any) (cons '() r))
((pair? p) (match-empty (car p) (match-empty (cdr p) r)))
((eq? p 'each-any) (cons '() r))
(else
(case (vector-ref p 0)
((each) (match-empty (vector-ref p 1) r))
((each+)
(match-empty
(vector-ref p 1)
(match-empty
(reverse (vector-ref p 2))
(match-empty (vector-ref p 3) r))))
((free-id atom) r)
((vector) (match-empty (vector-ref p 1) r))
(else (error 'syntax-dispatch "invalid pattern" p)))))))
(define combine
(lambda (r* r)
(if (null? (car r*))
r
(cons (map car r*) (combine (map cdr r*) r)))))
(define match*
(lambda (e p m* s* r)
(cond
((null? p) (and (null? e) r))
((pair? p)
(and (pair? e)
(match (car e) (car p) m* s*
(match (cdr e) (cdr p) m* s* r))))
((eq? p 'each-any)
(let ((l (match-each-any e m* s*))) (and l (cons l r))))
(else
(case (vector-ref p 0)
((each)
(if (null? e)
(match-empty (vector-ref p 1) r)
(let ((r* (match-each e (vector-ref p 1) m* s*)))
(and r* (combine r* r)))))
((free-id)
(and (symbol? e)
(free-id=? (stx e m* s*) (vector-ref p 1))
r))
((each+)
(let-values (((xr* y-pat r)
(match-each+ e (vector-ref p 1)
(vector-ref p 2) (vector-ref p 3) m* s* r)))
(and r
(null? y-pat)
(if (null? xr*)
(match-empty (vector-ref p 1) r)
(combine xr* r)))))
((atom) (and (equal? (vector-ref p 1) (strip e m*)) r))
((vector)
(and (vector? e)
(match (vector->list e) (vector-ref p 1) m* s* r)))
(else (error 'syntax-dispatch "invalid pattern" p)))))))
(define match
(lambda (e p m* s* r)
(cond
((not r) #f)
((eq? p '_) r)
((eq? p 'any) (cons (stx e m* s*) r))
((stx? e)
(let-values (((m* s*) (join-wraps m* s* e)))
(match (stx-expr e) p m* s* r)))
(else (match* e p m* s* r)))))
(match e p '() '() '())))
(define ellipsis?
(lambda (x)
(and (id? x) (free-id=? x (scheme-stx '...)))))
(define syntax-case-transformer
(let ()
(define build-dispatch-call
(lambda (pvars expr y r mr)
(let ([ids (map car pvars)]
[levels (map cdr pvars)])
(let ([labels (map gen-label ids)]
[new-vars (map gen-lexical ids)])
(let ([body
(chi-expr
(add-subst (make-full-rib ids labels) expr)
(extend-env*
labels
(map (lambda (var level)
(make-binding 'syntax (cons var level)))
new-vars
(map cdr pvars))
r)
mr)])
(build-application no-source
(build-primref no-source 'apply)
(list (build-lambda no-source new-vars body) y)))))))
(define invalid-ids-error
(lambda (id* e class)
(let find ((id* id*) (ok* '()))
(if (null? id*)
(stx-error e) ; shouldn't happen
(if (id? (car id*))
(if (bound-id-member? (car id*) ok*)
(syntax-error (car id*) "duplicate " class)
(find (cdr id*) (cons (car id*) ok*)))
(syntax-error (car id*) "invalid " class))))))
(define gen-clause
(lambda (x keys clauses r mr pat fender expr)
(let-values (((p pvars) (convert-pattern pat keys)))
(cond
((not (distinct-bound-ids? (map car pvars)))
(invalid-ids-error (map car pvars) pat "pattern variable"))
((not (andmap (lambda (x) (not (ellipsis? (car x)))) pvars))
(stx-error pat "misplaced ellipsis in syntax-case pattern"))
(else
(let ((y (gen-lexical 'tmp)))
(let ([test
(cond
[(eq? fender #t) y]
[else
(let ([call
(build-dispatch-call
pvars fender y r mr)])
(build-conditional no-source
(build-lexical-reference no-source y)
call
(build-data no-source #f)))])])
(let ([conseq
(build-dispatch-call pvars expr
(build-lexical-reference no-source y)
r mr)])
(let ([altern
(gen-syntax-case x keys clauses r mr)])
(build-application no-source
(build-lambda no-source (list y)
(build-conditional no-source test conseq altern))
(list
(build-application no-source
(build-primref no-source 'syntax-dispatch)
(list
(build-lexical-reference no-source x)
(build-data no-source p))))))))))))))
(define gen-syntax-case
(lambda (x keys clauses r mr)
(if (null? clauses)
(build-application no-source
(build-primref no-source 'syntax-error)
(list (build-lexical-reference no-source x)))
(syntax-match (car clauses) ()
[(pat expr)
(if (and (id? pat)
(not (bound-id-member? pat keys))
(not (ellipsis? pat)))
(if (free-id=? pat (scheme-stx '_))
(chi-expr expr r mr)
(let ([lab (gen-label pat)]
[lex (gen-lexical pat)])
(let ([body
(chi-expr
(add-subst (make-full-rib (list pat) (list lab)) expr)
(extend-env lab (make-binding 'syntax (cons lex 0)) r)
mr)])
(build-application no-source
(build-lambda no-source (list lex) body)
(list (build-lexical-reference no-source x))))))
(gen-clause x keys (cdr clauses) r mr pat #t expr))]
[(pat fender expr)
(gen-clause x keys (cdr clauses) r mr pat fender expr)]))))
(lambda (e r mr)
(syntax-match e ()
[(_ expr (keys ...) clauses ...)
(begin
(unless (andmap (lambda (x) (and (id? x) (not (ellipsis? x)))) keys)
(stx-error e "invalid literals"))
(let ((x (gen-lexical 'tmp)))
(let ([body (gen-syntax-case x keys clauses r mr)])
(build-application no-source
(build-lambda no-source (list x) body)
(list (chi-expr expr r mr))))))]))))
(define syntax-transformer
(let ()
(define gen-syntax
(lambda (src e r maps ellipsis? vec?)
(syntax-match e ()
[dots (ellipsis? dots)
(stx-error src "misplaced ellipsis in syntax form")]
[id (id? id)
(let* ([label (id->label e)]
[b (label->binding label r)])
(if (eq? (binding-type b) 'syntax)
(let-values ([(var maps)
(let ((var.lev (binding-value b)))
(gen-ref src (car var.lev) (cdr var.lev) maps))])
(values (list 'ref var) maps))
(values (list 'quote e) maps)))]
[(dots e) (ellipsis? dots)
(if vec?
(stx-error src "misplaced ellipsis in syntax form")
(gen-syntax src e r maps (lambda (x) #f) #f))]
[(x dots . y) (ellipsis? dots)
(let f ([y y]
[k (lambda (maps)
(let-values ([(x maps)
(gen-syntax src x r
(cons '() maps) ellipsis? #f)])
(if (null? (car maps))
(stx-error src
"extra ellipsis in syntax form")
(values (gen-map x (car maps)) (cdr maps)))))])
(syntax-match y ()
[() (k maps)]
[(dots . y) (ellipsis? dots)
(f y
(lambda (maps)
(let-values ([(x maps) (k (cons '() maps))])
(if (null? (car maps))
(stx-error src "extra ellipsis in syntax form")
(values (gen-mappend x (car maps)) (cdr maps))))))]
[_
(let-values ([(y maps)
(gen-syntax src y r maps ellipsis? vec?)])
(let-values (((x maps) (k maps)))
(values (gen-append x y) maps)))]))]
[(x . y)
(let-values ([(xnew maps)
(gen-syntax src x r maps ellipsis? #f)])
(let-values ([(ynew maps)
(gen-syntax src y r maps ellipsis? vec?)])
(values (gen-cons e x y xnew ynew) maps)))]
[#(ls ...)
(let-values ([(lsnew maps)
(gen-syntax src ls r maps ellipsis? #t)])
(values (gen-vector e ls lsnew) maps))]
[() (values '(quote ()) maps)]
[_ (values `(quote ,e) maps)])))
(define gen-ref
(lambda (src var level maps)
(if (= level 0)
(values var maps)
(if (null? maps)
(stx-error src "missing ellipsis in syntax form")
(let-values (((outer-var outer-maps)
(gen-ref src var (- level 1) (cdr maps))))
(cond
[(assq outer-var (car maps)) =>
(lambda (b) (values (cdr b) maps))]
[else
(let ((inner-var (gen-lexical 'tmp)))
(values
inner-var
(cons
(cons (cons outer-var inner-var) (car maps))
outer-maps)))]))))))
(define gen-append
(lambda (x y)
(if (equal? y '(quote ())) x `(append ,x ,y))))
(define gen-mappend
(lambda (e map-env)
`(apply (primitive append) ,(gen-map e map-env))))
(define gen-map
(lambda (e map-env)
(let ((formals (map cdr map-env))
(actuals (map (lambda (x) `(ref ,(car x))) map-env)))
(cond
; identity map equivalence:
; (map (lambda (x) x) y) == y
[(eq? (car e) 'ref)
(car actuals)]
; eta map equivalence:
; (map (lambda (x ...) (f x ...)) y ...) == (map f y ...)
[(andmap
(lambda (x) (and (eq? (car x) 'ref) (memq (cadr x) formals)))
(cdr e))
(let ([args (map (let ((r (map cons formals actuals)))
(lambda (x) (cdr (assq (cadr x) r))))
(cdr e))])
`(map (primitive ,(car e)) . ,args))]
[else (list* 'map (list 'lambda formals e) actuals)]))))
(define gen-cons
(lambda (e x y xnew ynew)
(case (car ynew)
[(quote)
(if (eq? (car xnew) 'quote)
(let ((xnew (cadr xnew)) (ynew (cadr ynew)))
(if (and (eq? xnew x) (eq? ynew y))
`(quote ,e)
`(quote ,(cons xnew ynew))))
(if (eq? (cadr ynew) '())
`(list ,xnew)
`(cons ,xnew ,ynew)))]
[(list) `(list ,xnew . ,(cdr ynew))]
[else `(cons ,xnew ,ynew)])))
(define gen-vector
(lambda (e ls lsnew)
(cond
[(eq? (car lsnew) 'quote)
(if (eq? (cadr lsnew) ls)
`(quote ,e)
`(quote #(,@(cadr lsnew))))]
[(eq? (car lsnew) 'list)
`(vector . ,(cdr lsnew))]
[else `(list->vector ,lsnew)])))
(define regen
(lambda (x)
(case (car x)
[(ref) (build-lexical-reference no-source (cadr x))]
[(primitive) (build-primref no-source (cadr x))]
[(quote) (build-data no-source (cadr x))]
[(lambda) (build-lambda no-source (cadr x) (regen (caddr x)))]
[(map)
(let ((ls (map regen (cdr x))))
(build-application no-source
(build-primref no-source 'map)
ls))]
[else
(build-application no-source
(build-primref no-source (car x))
(map regen (cdr x)))])))
(lambda (e r mr)
(syntax-match e ()
[(_ x)
(let-values (((e maps) (gen-syntax e x r '() ellipsis? #f)))
(regen e))]))))
(define core-macro-transformer
(lambda (name)
(case name
[(quote) quote-transformer]
[(lambda) lambda-transformer]
[(case-lambda) case-lambda-transformer]
[(let-values) let-values-transformer]
[(letrec) letrec-transformer]
[(letrec*) letrec*-transformer]
[(case) case-transformer]
[(if) if-transformer]
[(when) when-transformer]
[(unless) unless-transformer]
[(parameterize) parameterize-transformer]
[(foreign-call) foreign-call-transformer]
[(syntax-case) syntax-case-transformer]
[(syntax) syntax-transformer]
[(type-descriptor) type-descriptor-transformer]
[else (error 'macro-transformer "cannot find ~s" name)])))
(define macro-transformer
(lambda (x)
(cond
[(procedure? x) x]
[(symbol? x)
(case x
[(define-record) define-record-macro]
[(include) include-macro]
[(cond) cond-macro]
[(let) let-macro]
[(do) do-macro]
[(or) or-macro]
[(and) and-macro]
[(let*) let*-macro]
[(syntax-rules) syntax-rules-macro]
[(quasiquote) quasiquote-macro]
[(with-syntax) with-syntax-macro]
[(identifier-syntax) identifier-syntax-macro]
[else (error 'macro-transformer "invalid macro ~s" x)])]
[else (error 'core-macro-transformer "invalid macro ~s" x)])))
(define (local-macro-transformer x)
(car x))
;;; chi procedures
(define chi-macro
(lambda (p e)
(let ([s ((macro-transformer p) (add-mark anti-mark e))])
(add-mark (gen-mark) s))))
(define chi-local-macro
(lambda (p e)
(let ([s ((local-macro-transformer p) (add-mark anti-mark e))])
(add-mark (gen-mark) s))))
(define (chi-global-macro p e)
(let ([lib (car p)]
[loc (cdr p)])
(visit-library lib)
(let ([x (symbol-value loc)])
(let ([transformer
(cond
[(procedure? x) x]
[else (error 'chi-global-macro "~s is not a procedure")])])
(let ([s (transformer (add-mark anti-mark e))])
(add-mark (gen-mark) s))))))
(define chi-expr*
(lambda (e* r mr)
;;; expand left to right
(cond
[(null? e*) '()]
[else
(let ([e (chi-expr (car e*) r mr)])
(cons e (chi-expr* (cdr e*) r mr)))])))
(define chi-application
(lambda (e r mr)
(syntax-match e ()
[(rator rands ...)
(let ([rator (chi-expr rator r mr)])
(build-application no-source
rator
(chi-expr* rands r mr)))])))
(define chi-expr
(lambda (e r mr)
(let-values ([(type value kwd) (syntax-type e r)])
(case type
[(core-macro)
(let ([transformer (core-macro-transformer value)])
(transformer e r mr))]
[(global)
(let* ([lib (car value)]
[loc (cdr value)])
((inv-collector) lib)
(build-global-reference no-source loc))]
[(core-prim)
(let ([name value])
(build-primref no-source name))]
[(call) (chi-application e r mr)]
[(lexical)
(let ([lex value])
(build-lexical-reference no-source lex))]
[(global-macro)
(chi-expr (chi-global-macro value e) r mr)]
[(local-macro) (chi-expr (chi-local-macro value e) r mr)]
[(macro) (chi-expr (chi-macro value e) r mr)]
[(constant)
(let ([datum value])
(build-data no-source datum))]
[(set!) (chi-set! e r mr)]
[(begin)
(syntax-match e ()
[(_ x x* ...)
(build-sequence no-source
(chi-expr* (cons x x*) r mr))])]
[(let-syntax letrec-syntax)
(syntax-match e ()
[(_ ([xlhs* xrhs*] ...) xbody xbody* ...)
(unless (valid-bound-ids? xlhs*)
(stx-error e "duplicate identifiers"))
(let* ([xlab* (map gen-label xlhs*)]
[xrib (make-full-rib xlhs* xlab*)]
[xb* (map (lambda (x)
(make-eval-transformer
(expand-transformer
(if (eq? type 'let-syntax) x (add-subst xrib x))
mr)))
xrhs*)])
(build-sequence no-source
(chi-expr*
(map (lambda (x) (add-subst xrib x)) (cons xbody xbody*))
(append (map cons xlab* xb*) r)
(append (map cons xlab* xb*) mr))))])]
[(displaced-lexical)
(stx-error e "identifier out of context")]
[(syntax) (stx-error e "reference to pattern variable outside a syntax form")]
[(define define-syntax module import)
(stx-error e "invalid expression")]
[else (error 'chi-expr "invalid type ~s for ~s" type
(strip e '())) (stx-error e)]))))
(define chi-set!
(lambda (e r mr)
(syntax-match e ()
[(_ x v) (id? x)
(let-values ([(type value kwd) (syntax-type x r)])
(case type
[(lexical)
(build-lexical-assignment no-source
value
(chi-expr v r mr))]
;;; FIXME: handle macro!
[else (stx-error e)]))])))
(define chi-lambda-clause
(lambda (fmls body* r mr)
(syntax-match fmls ()
[(x* ...)
(if (valid-bound-ids? x*)
(let ([lex* (map gen-lexical x*)]
[lab* (map gen-label x*)])
(values
lex*
(chi-internal
(add-subst
(make-full-rib x* lab*)
body*)
(add-lexicals lab* lex* r)
mr)))
(stx-error fmls "invalid fmls"))]
[(x* ... . x)
(if (valid-bound-ids? (cons x x*))
(let ([lex* (map gen-lexical x*)]
[lab* (map gen-label x*)]
[lex (gen-lexical x)]
[lab (gen-label x)])
(values
(append lex* lex)
(chi-internal
(add-subst
(make-full-rib (cons x x*) (cons lab lab*))
body*)
(add-lexicals (cons lab lab*)
(cons lex lex*)
r)
mr)))
(stx-error fmls "invalid fmls"))]
[_ (stx-error fmls "invalid fmls")])))
(define chi-lambda-clause*
(lambda (fmls* body** r mr)
(cond
[(null? fmls*) (values '() '())]
[else
(let-values ([(a b)
(chi-lambda-clause (car fmls*) (car body**) r mr)])
(let-values ([(a* b*)
(chi-lambda-clause* (cdr fmls*) (cdr body**) r mr)])
(values (cons a a*) (cons b b*))))])))
(define chi-rhs
(lambda (rhs r mr)
(case (car rhs)
[(defun)
(let ([x (cdr rhs)])
(let ([fmls (car x)] [body* (cdr x)])
(let-values ([(fmls body)
(chi-lambda-clause fmls body* r mr)])
(build-lambda no-source fmls body))))]
[(expr)
(let ([expr (cdr rhs)])
(chi-expr expr r mr))]
[(top-expr)
(let ([expr (cdr rhs)])
(build-sequence no-source
(list (chi-expr expr r mr)
(build-void))))]
[else (error 'chi-rhs "invalid rhs ~s" rhs)])))
(define chi-rhs*
(lambda (rhs* r mr)
(let f ([ls rhs*])
(cond ;;; chi in order
[(null? ls) '()]
[else
(let ([a (chi-rhs (car ls) r mr)])
(cons a (f (cdr ls))))]))))
(define find-bound=?
(lambda (x lhs* rhs*)
(cond
[(null? lhs*) #f]
[(bound-id=? x (car lhs*)) (car rhs*)]
[else (find-bound=? x (cdr lhs*) (cdr rhs*))])))
(define (find-dups ls)
(let f ([ls ls] [dups '()])
(cond
[(null? ls) dups]
[(find-bound=? (car ls) (cdr ls) (cdr ls)) =>
(lambda (x) (f (cdr ls) (cons (list (car ls) x) dups)))]
[else (f (cdr ls) dups)])))
(define chi-internal
(lambda (e* r mr)
(let ([rib (make-empty-rib)])
(let-values ([(e* r mr lex* rhs* mod** kwd*)
(chi-body* (map (lambda (x) (add-subst rib x))
(syntax->list e*))
r mr '() '() '() '() rib #f)])
(when (null? e*)
(stx-error e* "no expression in body"))
(let ([rhs* (chi-rhs* rhs* r mr)]
[init* (chi-expr* (append (apply append (reverse mod**)) e*) r mr)])
(build-letrec* no-source
(reverse lex*) (reverse rhs*)
(build-sequence no-source init*)))))))
(define chi-internal-module
(lambda (e r mr lex* rhs* mod** kwd*)
(define parse-module
(lambda (e)
(syntax-match e ()
[(_ (export* ...) b* ...)
(begin
(unless (andmap id? export*)
(stx-error e "module exports must be identifiers"))
(values #f export* b*))]
[(_ name (export* ...) b* ...)
(begin
(unless (id? name)
(stx-error e "module name must be an identifier"))
(unless (andmap id? export*)
(stx-error e "module exports must be identifiers"))
(values name export* b*))])))
(let-values ([(name exp-id* e*) (parse-module e)])
(let* ([rib (make-empty-rib)]
[e* (map (lambda (x) (add-subst rib x))
(syntax->list e*))])
(let-values ([(e* r mr lex* rhs* mod** kwd*)
(chi-body* e* r mr lex* rhs* mod** kwd* rib #f)])
(let ([exp-lab*
(map (lambda (x)
(or (id->label (add-subst rib x))
(stx-error x "cannot find export")))
exp-id*)]
[mod** (cons e* mod**)])
(if (not name) ;;; explicit export
(values lex* rhs* exp-id* exp-lab* r mr mod** kwd*)
(let ([lab (gen-label 'module)]
[iface (cons exp-id* exp-lab*)])
(values lex* rhs*
(list name) ;;; FIXME: module cannot
(list lab) ;;; export itself yet
(cons (cons lab (cons '$module iface)) r)
(cons (cons lab (cons '$module iface)) mr)
mod** kwd*)))))))))
(define chi-body*
(lambda (e* r mr lex* rhs* mod** kwd* rib top?)
(cond
[(null? e*) (values e* r mr lex* rhs* mod** kwd*)]
[else
(let ([e (car e*)])
(let-values ([(type value kwd) (syntax-type e r)])
(let ([kwd* (cons-id kwd kwd*)])
(case type
[(define)
(let-values ([(id rhs) (parse-define e)])
(when (bound-id-member? id kwd*)
(stx-error e "cannot redefine keyword"))
(let ([lex (gen-lexical id)]
[lab (gen-label id)])
(extend-rib/check! rib id lab)
(chi-body* (cdr e*)
(add-lexical lab lex r) mr
(cons lex lex*) (cons rhs rhs*)
mod** kwd* rib top?)))]
[(define-syntax)
(let-values ([(id rhs) (parse-define-syntax e)])
(when (bound-id-member? id kwd*)
(stx-error e "cannot redefine keyword"))
(let ([lab (gen-label id)]
[expanded-rhs (expand-transformer rhs mr)])
(extend-rib/check! rib id lab)
(let ([b (make-eval-transformer expanded-rhs)])
(chi-body* (cdr e*)
(cons (cons lab b) r) (cons (cons lab b) mr)
lex* rhs* mod** kwd* rib top?))))]
[(let-syntax letrec-syntax)
(syntax-match e ()
[(_ ([xlhs* xrhs*] ...) xbody* ...)
(unless (valid-bound-ids? xlhs*)
(stx-error e "duplicate identifiers"))
(let* ([xlab* (map gen-label xlhs*)]
[xrib (make-full-rib xlhs* xlab*)]
[xb* (map (lambda (x)
(make-eval-transformer
(expand-transformer
(if (eq? type 'let-syntax) x (add-subst xrib x))
mr)))
xrhs*)])
(chi-body*
(append (map (lambda (x) (add-subst xrib x)) xbody*) (cdr e*))
(append (map cons xlab* xb*) r)
(append (map cons xlab* xb*) mr)
lex* rhs* mod** kwd* rib top?))])]
[(begin)
(syntax-match e ()
[(_ x* ...)
(chi-body* (append x* (cdr e*))
r mr lex* rhs* mod** kwd* rib top?)])]
[(global-macro)
(chi-body*
(cons (add-subst rib (chi-global-macro value e)) (cdr e*))
r mr lex* rhs* mod** kwd* rib top?)]
[(local-macro)
(chi-body*
(cons (add-subst rib (chi-local-macro value e)) (cdr e*))
r mr lex* rhs* mod** kwd* rib top?)]
[(macro)
(chi-body*
(cons (add-subst rib (chi-macro value e)) (cdr e*))
r mr lex* rhs* mod** kwd* rib top?)]
[(module)
(let-values ([(lex* rhs* m-exp-id* m-exp-lab* r mr mod** kwd*)
(chi-internal-module e r mr lex* rhs* mod** kwd*)])
(for-each
(lambda (id lab) (extend-rib/check! rib id lab))
m-exp-id* m-exp-lab*)
(chi-body* (cdr e*) r mr lex* rhs* mod** kwd* rib top?))]
[(import)
(let ()
(define (module-import e r)
(syntax-match e ()
[(_ id) (id? id)
(let-values ([(type value kwd) (syntax-type id r)])
(case type
[($module)
(let ([iface value])
(let ([id* (car iface)] [lab* (cdr iface)])
(values id* lab*)))]
[else (stx-error e "invalid import")]))]))
(let-values ([(id* lab*) (module-import e r)])
(for-each
(lambda (id lab) (extend-rib/check! rib id lab))
id* lab*)))
(chi-body* (cdr e*) r mr lex* rhs* mod** kwd* rib top?)]
[else
(if top?
(chi-body* (cdr e*) r mr
(cons (gen-lexical 'dummy) lex*)
(cons (cons 'top-expr e) rhs*)
mod** kwd* rib top?)
(values e* r mr lex* rhs* mod** kwd*))]))))])))
(define set-global-macro-binding!
(lambda (loc b) (error 'set-global-macro-binding! "not yet")))
(define gen-global-macro-binding
(lambda (id) (error 'gen-global-macro-binding "not yet")))
(define gen-global-var-binding
(lambda (id ctxt)
(let ([label (id->label id)])
(let ([b (imported-label->binding label)])
(case (binding-type b)
[(global)
(let ([x (binding-value b)])
(let ([lib (car x)] [loc (cdr x)])
(cond
[(eq? lib (interaction-library))
loc]
[else
(stx-error ctxt "cannot modify imported binding")])))]
[else (stx-error ctxt "cannot modify")])))))
(define chi-top*
(lambda (e* init*)
(cond
[(null? e*) init*]
[else
(let ([e (car e*)])
(let-values ([(type value kwd) (syntax-type e '())])
(case type
[(define)
(let-values ([(id rhs) (parse-define e)])
(let ([loc (gen-global-var-binding id e)])
(let ([rhs (chi-rhs rhs '() '())])
(chi-top* (cdr e*) (cons (cons loc rhs) init*)))))]
[(define-syntax)
(let-values ([(id rhs) (parse-define-syntax e)])
(let ([loc (gen-global-macro-binding id)])
(let ([expanded-rhs (expand-transformer rhs '())])
(let ([b (make-eval-transformer expanded-rhs)])
(set-global-macro-binding! loc b)
(chi-top* (cdr e*) init*)))))]
[(begin)
(syntax-match e ()
[(_ x* ...)
(chi-top* (append x* (cdr e*)) init*)])]
[(global-macro)
(chi-top* (cons (chi-global-macro value e) (cdr e*)) init*)]
[(local-macro)
(chi-top* (cons (chi-local-macro value e) (cdr e*)) init*)]
[(macro)
(chi-top* (cons (chi-macro value e) (cdr e*)) init*)]
[else
(chi-top* (cdr e*)
(cons (cons #f (chi-expr e '() '()))
init*))])))])))
(define (expand-transformer expr r)
(let ([rtc (make-collector)])
(let ([expanded-rhs
(parameterize ([inv-collector rtc]
[vis-collector (lambda (x) (void))])
(chi-expr expr r r))])
(for-each
(let ([mark-visit (vis-collector)])
(lambda (x)
(invoke-library x)
(mark-visit x)))
(rtc))
expanded-rhs)))
(define (parse-exports exp*)
(let f ([exp* exp*] [int* '()] [ext* '()])
(cond
[(null? exp*)
(let ([id* (map (lambda (x) (stx x top-mark* '())) ext*)])
(unless (valid-bound-ids? id*)
(error #f "duplicate exports of ~s" (find-dups id*))))
(values int* ext*)]
[else
(syntax-match (car exp*) ()
[(rename (i* e*) ...)
(begin
(unless (and (eq? rename 'rename) (andmap symbol? i*) (andmap symbol? e*))
(error #f "invalid export specifier ~s" (car exp*)))
(f (cdr exp*) (append i* int*) (append e* ext*)))]
[ie
(begin
(unless (symbol? ie) (error #f "invalid export ~s" ie))
(f (cdr exp*) (cons ie int*) (cons ie ext*)))])])))
(define parse-library
(lambda (e)
(syntax-match e ()
[(_ (name name* ...)
(export exp* ...)
(import imp* ...)
b* ...)
(if (and (eq? export 'export)
(eq? import 'import)
(symbol? name)
(andmap symbol? name*))
(let-values ([(exp-int* exp-ext*) (parse-exports exp*)])
(values (cons name name*) exp-int* exp-ext* imp* b*))
(error who "malformed library ~s" e))]
[_ (error who "malformed library ~s" e)])))
(define (set-cons x ls)
(cond
[(memq x ls) ls]
[else (cons x ls)]))
(define (set-union ls1 ls2)
(cond
[(null? ls1) ls2]
[(memq (car ls1) ls2) (set-union (cdr ls1) ls2)]
[else (cons (car ls1) (set-union (cdr ls1) ls2))]))
(define (get-import-subst/libs imp*)
(define (insert-to-subst a subst)
(let ([name (car a)] [label (cdr a)])
(cond
[(assq name subst) =>
(lambda (x)
(cond
[(eq? (cdr x) label) subst]
[else
(error 'import
"two imports of ~s with different bindings"
name)]))]
[else
(cons a subst)])))
(define (merge-substs s subst)
(cond
[(null? s) subst]
[else
(insert-to-subst (car s)
(merge-substs (cdr s) subst))]))
(define (exclude* sym* subst)
(define (exclude sym subst)
(cond
[(null? subst)
(error 'import "cannot rename unbound identifier ~s" sym)]
[(eq? sym (caar subst))
(values (cdar subst) (cdr subst))]
[else
(let ([a (car subst)])
(let-values ([(old subst) (exclude sym (cdr subst))])
(values old (cons a subst))))]))
(cond
[(null? sym*) (values '() subst)]
[else
(let-values ([(old subst) (exclude (car sym*) subst)])
(let-values ([(old* subst) (exclude* (cdr sym*) subst)])
(values (cons old old*) subst)))]))
(define (find* sym* subst)
(map (lambda (x)
(cond
[(assq x subst) => cdr]
[else (error 'import "cannot find identifier ~s" x)]))
sym*))
(define (rem* sym* subst)
(let f ([subst subst])
(cond
[(null? subst) '()]
[(memq (caar subst) sym*) (f (cdr subst))]
[else (cons (car subst) (f (cdr subst)))])))
(define (get-import spec)
(define (remove-dups ls)
(cond
[(null? ls) '()]
[(memq (car ls) (cdr ls)) (remove-dups (cdr ls))]
[else (cons (car ls) (remove-dups (cdr ls)))]))
(unless (pair? spec)
(error 'import "invalid import spec ~s" spec))
(case (car spec)
[(rename)
(syntax-match spec ()
[(_ isp (old* new*) ...)
(begin
(unless (and (andmap symbol? old*) (andmap symbol? new*))
(error 'import "invalid import spec ~s" spec))
(let-values ([(subst lib) (get-import isp)])
(let ([old-label* (find* old* subst)])
(let ([subst (rem* old* subst)])
;;; FIXME: make sure map is valid
(values (merge-substs (map cons new* old-label*) subst)
lib)))))]
[_ (error 'import "invalid rename spec ~s" spec)])]
[(except)
(syntax-match spec ()
[(_ isp sym* ...)
(begin
(unless (andmap symbol? sym*)
(error 'import "invalid import spec ~s" spec))
(let-values ([(subst lib) (get-import isp)])
(values (rem* sym* subst) lib)))]
[_ (error 'import "invalid import spec ~s" spec)])]
[(only)
(syntax-match spec ()
[(_ isp sym* ...)
(begin
(unless (andmap symbol? sym*)
(error 'import "invalid import spec ~s" spec))
(let-values ([(subst lib) (get-import isp)])
(let ([sym* (remove-dups sym*)])
(let ([lab* (find* sym* subst)])
(values (map cons sym* lab*) lib)))))]
[_ (error 'import "invalid import spec ~s" spec)])]
[(prefix)
(syntax-match spec ()
[(_ isp p)
(let ([s (if (symbol? p)
(symbol->string p)
(error 'import "invalid prefix"))])
(let-values ([(subst lib) (get-import isp)])
(values
(map
(lambda (x)
(cons
(string->symbol
(string-append s
(symbol->string (car x))))
(cdr x)))
subst)
lib)))]
[_ (error 'import "invalid prefix form ~s" spec)])]
[else
(let ([lib (find-library-by-name spec)])
(unless lib
(error 'import "cannot find library satisfying ~s" spec))
(let ([s (library-subst lib)])
(values s lib)))]))
(cond
[(null? imp*) (values '() '())]
[else
(let-values ([(subst1 lib1*)
(get-import-subst/libs (cdr imp*))])
(let-values ([(subst2 lib2) (get-import (car imp*))])
(values (merge-substs subst1 subst2)
(set-cons lib2 lib1*))))]))
(define (make-top-rib subst)
(let ([rib (make-empty-rib)])
(for-each
(lambda (x)
(let ([name (car x)] [label (cdr x)])
(extend-rib! rib (stx name top-mark* '()) label)))
subst)
rib))
(define (make-collector)
(let ([ls '()])
(case-lambda
[() ls]
[(x) (set! ls (set-cons x ls))])))
(define inv-collector
(make-parameter
(lambda args
(error 'inv-collector "not initialized"))
(lambda (x)
(unless (procedure? x)
(error 'inv-collector "~s is not a procedure" x))
x)))
(define vis-collector
(make-parameter
(lambda args
(error 'vis-collector "not initialized"))
(lambda (x)
(unless (procedure? x)
(error 'vis-collector "~s is not a procedure" x))
x)))
(define chi-library-internal
(lambda (e* rib top?)
(let-values ([(e* r mr lex* rhs* mod** _kwd*)
(chi-body* e* '() '() '() '() '() '() rib top?)])
(values (append (apply append (reverse mod**)) e*)
r mr (reverse lex*) (reverse rhs*)))))
(define core-library-expander
(lambda (e)
(let-values ([(name exp-int* exp-ext* imp* b*) (parse-library e)])
(let-values ([(subst imp*) (get-import-subst/libs imp*)])
(let ([rib (make-top-rib subst)])
(let ([b* (map (lambda (x) (stx x top-mark* (list rib))) b*)]
[rtc (make-collector)]
[vtc (make-collector)])
(parameterize ([inv-collector rtc]
[vis-collector vtc])
(let-values ([(init* r mr lex* rhs*)
(chi-library-internal b* rib #f)])
(seal-rib! rib)
(let ([rhs* (chi-rhs* rhs* r mr)])
(let ([invoke-body (if (and (null? init*) (null? lex*))
(build-void)
(build-sequence no-source
(append
(map build-export lex*)
(chi-expr* init* r mr))))])
(unseal-rib! rib)
(let ([export-subst (make-export-subst exp-int* exp-ext* rib)])
(let-values ([(export-env macro*)
(make-export-env/macros r)])
(values
name imp* (rtc) (vtc)
(build-letrec* no-source lex* rhs* invoke-body)
macro*
export-subst export-env)))))))))))))
(define (parse-top-level-program e*)
(syntax-match e* ()
[((import imp* ...) b* ...) (eq? import 'import)
(values imp* b*)]
[_ (error "invalid syntax of top-level program")]))
(define top-level-expander
(lambda (e*)
(let-values ([(imp* b*) (parse-top-level-program e*)])
(let-values ([(subst imp*) (get-import-subst/libs imp*)])
(let ([rib (make-top-rib subst)])
(let ([b* (map (lambda (x) (stx x top-mark* (list rib))) b*)]
[rtc (make-collector)]
[vtc (make-collector)])
(parameterize ([inv-collector rtc]
[vis-collector vtc])
(let-values ([(init* r mr lex* rhs*)
(chi-library-internal b* rib #t)])
(seal-rib! rib)
(let ([rhs* (chi-rhs* rhs* r mr)])
(let ([invoke-body (if (null? init*)
(build-void)
(build-sequence no-source
(chi-expr* init* r mr)))])
(unseal-rib! rib)
(values (rtc)
(build-letrec* no-source
lex* rhs* invoke-body))))))))))))
(define-record eval-environment (subst imp*))
(define environment
(lambda imp*
(let-values ([(subst imp*) (get-import-subst/libs imp*)])
(make-eval-environment subst imp*))))
(define environment?
(lambda (x) (eval-environment? x)))
(define eval
(lambda (x env)
(unless (eval-environment? env)
(error 'eval "~s is not an environment" env))
(let ([subst (eval-environment-subst env)])
(let ([rib (make-top-rib subst)])
(let ([x (stx x top-mark* (list rib))]
[rtc (make-collector)]
[vtc (make-collector)])
(let ([x
(parameterize ([inv-collector rtc]
[vis-collector vtc])
(chi-expr x '() '()))])
(seal-rib! rib)
(for-each invoke-library (rtc))
(eval-core x)))))))
(define (visit! macro*)
(for-each (lambda (x)
(let ([loc (car x)] [proc (cadr x)])
(set-symbol-value! loc proc)))
macro*))
(define (build-visit-code macro*)
(if (null? macro*)
(build-void)
(build-sequence no-source
(map (lambda (x)
(let ([loc (car x)] [src (cddr x)])
(build-global-assignment no-source loc src)))
macro*))))
(define (library-expander x)
(let-values ([(name imp* inv* vis* invoke-code macro* export-subst export-env)
(core-library-expander x)])
(let ([id (gensym)]
[name name]
[ver '()] ;;; FIXME
[imp* (map library-spec imp*)]
[vis* (map library-spec vis*)]
[inv* (map library-spec inv*)])
(install-library id name ver
imp* vis* inv* export-subst export-env
(lambda () (visit! macro*))
(lambda () (eval-core invoke-code))
#t)
;(pretty-print (build-visit-code macro*))
(values invoke-code
(build-visit-code macro*)
export-subst export-env))))
(define (boot-library-expand x)
(let-values ([(invoke-code visit-code export-subst export-env)
(library-expander x)])
(values invoke-code export-subst export-env)))
(define build-export
(lambda (x)
;;; exports use the same gensym
`(#%$set-symbol-value! ',x ,x)))
(define (make-export-subst int* ext* rib)
(map
(lambda (int ext)
(let* ([id (stx int top-mark* (list rib))]
[label (id->label id)])
(unless label
(stx-error id "cannot export unbound identifier"))
(cons ext label)))
int* ext*))
(define (make-export-env/macros r)
(let f ([r r] [env '()] [macro* '()])
(cond
[(null? r) (values env macro*)]
[else
(let ([x (car r)])
(let ([label (car x)] [b (cdr x)])
(case (binding-type b)
[(lexical)
(f (cdr r)
(cons (list* label 'global (binding-value b)) env)
macro*)]
[(local-macro)
(let ([loc (gensym)])
(f (cdr r)
(cons (list* label 'global-macro loc) env)
(cons (cons loc (binding-value b)) macro*)))]
[($rtd $module) (f (cdr r) (cons x env) macro*)]
[else
(error #f "don't know how to export ~s ~s"
(binding-type b) (binding-value b))])))])))
(define generate-temporaries
(lambda (ls)
(unless (list? ls)
(error 'generate-temporaries "~s is not a list"))
(map (lambda (x) (stx (gensym 't) top-mark* '())) ls)))
(define free-identifier=?
(lambda (x y)
(if (id? x)
(if (id? y)
(free-id=? x y)
(error 'free-identifier=? "~s is not an identifier" y))
(error 'free-identifier=? "~s is not an identifier" x))))
(define bound-identifier=?
(lambda (x y)
(if (id? x)
(if (id? y)
(bound-id=? x y)
(error 'bound-identifier=? "~s is not an identifier" y))
(error 'bound-identifier=? "~s is not an identifier" x))))
(define syntax-error
(lambda (x . args)
(unless (andmap string? args)
(error 'syntax-error "invalid argument ~s" args))
(error #f "~a: ~s"
(apply string-append args)
(strip x '()))))
(define identifier? (lambda (x) (id? x)))
(define datum->syntax
(lambda (id datum)
(if (id? id)
(datum->stx id datum)
(error 'datum->syntax "~s is not an identifier" id))))
(define syntax->datum
(lambda (x) (stx->datum x)))
(define eval-r6rs-top-level
(lambda (x*)
(let-values ([(lib* invoke-code) (top-level-expander x*)])
(for-each invoke-library lib*)
(eval-core invoke-code)
(void))))
(define eval-top-level
(lambda (x)
(define (eval-binding x)
(let ([loc (car x)] [expr (cdr x)])
(cond
[loc (set-symbol-value! loc (eval-core expr))]
[else (eval-core expr)])))
(let ([rtc (make-collector)]
[vtc (make-collector)])
(let ([init*
(parameterize ([inv-collector rtc]
[vis-collector vtc]
[interaction-library
(find-library-by-name '(ikarus interaction))])
(chi-top* (list (stx x top-mark* '())) '()))])
(for-each invoke-library (rtc))
(cond
[(null? init*) (void)]
[else
(for-each eval-binding (reverse (cdr init*)))
(eval-binding (car init*))])))))
;;; FIXME: export the rest of the syntax-case procedures
(set-rtd-printer! (type-descriptor eval-environment)
(lambda (x p)
(unless (eval-environment? x)
(error 'record-type-printer "not an environment"))
(display (format "#<environment>") p)))
(current-library-expander
(lambda (x)
(library-expander x)
(void)))
)