;--------------------------------------------------------------------------------------------- ; Transformer and Compiler ;--------------------------------------------------------------------------------------------- (load "s.scm") ;--------------------------------------------------------------------------------------------- ; Utils ;--------------------------------------------------------------------------------------------- (define set-member? (lambda (x s) (cond [(null? s) #f] [(eq? x (car s)) #t] [else (set-member? x (cdr s))]))) (define set-cons (lambda (x s) (if (set-member? x s) s (cons x s)))) (define set-union (lambda (s1 s2) (if (null? s1) s2 (set-union (cdr s1) (set-cons (car s1) s2))))) (define set-minus (lambda (s1 s2) (if (null? s1) '() (if (set-member? (car s1) s2) (set-minus (cdr s1) s2) (cons (car s1) (set-minus (cdr s1) s2)))))) (define set-intersect (lambda (s1 s2) (if (null? s1) '() (if (set-member? (car s1) s2) (cons (car s1) (set-intersect (cdr s1) s2)) (set-intersect (cdr s1) s2))))) (define-syntax record-case (syntax-rules (else) [(record-case (pa . ir) clause ...) (let ([id (pa . ir)]) (record-case id clause ...))] [(record-case id) 'record-case-miss] [(record-case id [else exp ...]) (begin exp ...)] [(record-case id [(key ...) ids exp ...] clause ...) (if (memq (car id) '(key ...)) (apply (lambda ids exp ...) (cdr id)) (record-case id clause ...))] [(record-case id [key ids exp ...] clause ...) (if (eq? (car id) 'key) (apply (lambda ids exp ...) (cdr id)) (record-case id clause ...))])) (define (sexp-match? pat x) (or (eq? pat '*) (and (eq? pat ') (or (symbol? x) (procedure? x))) (and (eq? pat ') (symbol? x)) (and (eq? pat ') (string? x)) (eqv? x pat) (and (pair? pat) (cond [(and (eq? (car pat) '...) (pair? (cdr pat)) (null? (cddr pat))) (eqv? x (cadr pat))] [(and (pair? (cdr pat)) (eq? (cadr pat) '...) (null? (cddr pat))) (let ([pat (car pat)]) (if (eq? pat '*) (list? x) (let loop ([lst x]) (or (null? lst) (and (pair? lst) (sexp-match? pat (car lst)) (loop (cdr lst)))))))] [else (and (pair? x) (sexp-match? (car pat) (car x)) (sexp-match? (cdr pat) (cdr x)))])) (and (vector? pat) (vector? x) (sexp-match? (vector->list pat) (vector->list x))) (and (box? pat) (box? x) (sexp-match? (unbox pat) (unbox x))))) (define-syntax sexp-case (syntax-rules (else) [(_ (key ...) clauses ...) (let ([atom-key (key ...)]) (sexp-case atom-key clauses ...))] [(_ key (else result1 result2 ...)) (begin result1 result2 ...)] [(_ key (pat result1 result2 ...)) (if (sexp-match? 'pat key) (begin result1 result2 ...))] [(_ key (pat result1 result2 ...) clause clauses ...) (if (sexp-match? 'pat key) (begin result1 result2 ...) (sexp-case key clause clauses ...))])) ; unique symbol generator (poor man's version) (define gensym (let ([gsc 0]) (lambda args ; (), (symbol), or (#f) for gsc reset (set! gsc (fx+ gsc 1)) (if (null? args) (string->symbol (string-append "#" (fixnum->string gsc 10))) (if (symbol? (car args)) (string->symbol (string-append (symbol->string (car args)) (string-append "#" (fixnum->string gsc 10)))) (set! gsc 0)))))) (define posq (lambda (x l) (let loop ([l l] [n 0]) (cond [(null? l) #f] [(eq? x (car l)) n] [else (loop (cdr l) (fx+ n 1))])))) (define rassq (lambda (x al) (and (pair? al) (let ([a (car al)]) (if (eq? x (cdr a)) a (rassq x (cdr al))))))) (define list-diff (lambda (l t) (if (or (null? l) (eq? l t)) '() (cons (car l) (list-diff (cdr l) t))))) (define (pair* x . more) (let loop ([x x] [rest more]) (if (null? rest) x (cons x (loop (car rest) (cdr rest)))))) (define (append* lst) (cond [(null? lst) '()] [(null? (cdr lst)) (car lst)] [else (append (car lst) (append* (cdr lst)))])) (define (string-append* l) (apply string-append l)) (define (andmap p l) (if (pair? l) (and (p (car l)) (andmap p (cdr l))) #t)) (define (ormap p l) (if (pair? l) (or (p (car l)) (ormap p (cdr l))) #f)) (define (list1? x) (and (pair? x) (null? (cdr x)))) (define (list1+? x) (and (pair? x) (list? (cdr x)))) (define (list2? x) (and (pair? x) (list1? (cdr x)))) (define (list2+? x) (and (pair? x) (list1+? (cdr x)))) (define (list3? x) (and (pair? x) (list2? (cdr x)))) (define (read-code-sexp port) ; for now, we will just use read with no support for circular structures (read-simple port)) (define (error* msg args) (raise (error-object #f msg args))) (define (warning* msg args) (print-error-message (string-append "Warning: " msg) args (current-error-port))) ;--------------------------------------------------------------------------------------------- ; Syntax of the Scheme Core language ;--------------------------------------------------------------------------------------------- ; -> (quote ) ; -> (const ) ; immutable variant of ref ; -> (ref ) ; -> (set! ) ; -> (set& ) ; -> (lambda ) where -> ( ...) | ( ... . ) | ; -> (lambda* ( ) ...) where -> ( ) ; -> (letcc ) ; -> (withcc ) ; -> (begin ...) ; -> (if ) ; -> (call ...) ; -> (integrable ...) where is an index in the integrables table ; -> (asm ) where is ig string leaving result in ac, e.g. "'2,'1+" ; NB: (begin) is legit, returns unspecified value ; on top level, these two extra core forms are legal: ; -> (define ) ; -> (define-syntax ) ; These names are bound to specials never returned by xform: ; (syntax ) ; (body ...) ; (syntax-lambda ( ...) ) ; (syntax-rules ( ...) ...) ; (syntax-length
) ; (syntax-error ...) (define idslist? (lambda (x) (cond [(null? x) #t] [(pair? x) (and (id? (car x)) (idslist? (cdr x)))] [else (id? x)]))) (define normalize-arity (lambda (arity) (if (and (list2? arity) (fixnum? (car arity)) (boolean? (cadr arity))) arity (let loop ([cnt 0] [l arity]) (cond [(pair? l) (loop (fx+ 1 cnt) (cdr l))] [(null? l) (list cnt #f)] [else (list cnt #t)]))))) ; convention for 'flattened' is to put rest arg if any at the front (define flatten-idslist (lambda (ilist) (if (list? ilist) ilist (let loop ([l ilist] [r '()]) (cond [(pair? l) (loop (cdr l) (cons (car l) r))] [else (if (null? l) (reverse! r) (cons l (reverse! r)))]))))) (define idslist-req-count (lambda (ilist) (if (pair? ilist) (fx+ 1 (idslist-req-count (cdr ilist))) 0))) ;--------------------------------------------------------------------------------------------- ; Macro transformer (from Scheme to Scheme Core) derived from Al Petrofsky's EIOD 1.17 ;--------------------------------------------------------------------------------------------- ; An environment is a procedure that accepts any identifier and access type and returns a ; denotation. Access type is one of these symbols: ref, set!, define, define-syntax. ; The denotation of an identifier is its macro location, which is a cell storing the ; identifier's current syntactic value. Location's value can be changed later. ; Special forms are either a symbol naming a builtin, or a transformer procedure ; that takes two arguments: a macro use and the environment of the macro use. ; -> | ; -> ; -> #& ; -> | ; -> | | ; -> syntax | quote | set! | set& | if | lambda | lambda* | ; letcc | withcc | body | begin | define | define-syntax | ; syntax-lambda | syntax-rules | syntax-length | syntax-error ; -> ; -> (define-syntax val-core? pair?) (define-syntax make-location box) (define-syntax location-val unbox) (define-syntax location-set-val! set-box!) (define (location-special? l) (not (pair? (unbox l)))) (define (new-id sym den getlits) (define p (list sym den getlits)) (lambda () p)) (define (old-sym id) (car (id))) (define (old-den id) (cadr (id))) (define (old-literals id) ((or (caddr (id)) (lambda () '())))) (define (id? x) (or (symbol? x) (procedure? x))) (define (id->sym id) (if (symbol? id) id (old-sym id))) ; take a possibly renamed target id, and find image for nid (define (id-rename-as id nid) (let loop ([id id]) (if (symbol? id) nid (let* ([lits (old-literals id)] [oid->id (rassq id lits)]) (unless oid->id (x-error "id-rename-as failed: not found in its own lits" id)) (let ([renamed-nid (loop (car oid->id))]) (cond [(assq renamed-nid lits) => cdr] [else renamed-nid])))))) ; Expand-time environments map identifiers (symbolic or thunked) to denotations, i.e. locations ; containing either a or a value. In normal case, value is (ref ), ; where is a key in run-time store, aka *globals*. Environments should allocate new locations ; as needed, so every identifier gets mapped to one. Expand-time environments are represented as ; two-argument procedures, where the second argument is an access type symbol. (define (extend-xenv-local id val env) (let ([loc (make-location val)]) (lambda (i at) (if (eq? id i) (case at [(ref set!) loc] [else #f]) (env i at))))) (define (add-local-var id gid env) (extend-xenv-local id (list 'ref gid) env)) (define (xenv-lookup env id at) (or (env id at) (error* "transformer: invalid identifier access" (list id at)))) (define (xenv-ref env id) (xenv-lookup env id 'ref)) (define (xform-sexp->datum sexp) (let conv ([sexp sexp]) (cond [(id? sexp) (id->sym sexp)] [(pair? sexp) (cons (conv (car sexp)) (conv (cdr sexp)))] [(vector? sexp) (list->vector (map conv (vector->list sexp)))] [else sexp]))) (define (x-error msg . args) (error* (string-append "transformer: " msg) args)) ; xform receives Scheme s-expressions and returns either Core Scheme ; (always a pair) or special-form, which is either a builtin (a symbol) or ; a transformer (a procedure). Appos? flag is true when the context can ; allow xform to return a special; otherwise, only is returned. (define (xform appos? sexp env) (cond [(id? sexp) (let ([hval (xform-ref sexp env)]) (cond [appos? hval] [(integrable? hval) ; integrable id-syntax (list 'ref (integrable-global hval))] [(procedure? hval) ; id-syntax (xform appos? (hval sexp env) env)] [(not (pair? hval)) ; special used out of context (x-error "improper use of syntax form" hval)] [else hval]))] ; core [(not (pair? sexp)) (xform-quote (list sexp) env)] [else (let* ([head (car sexp)] [tail (cdr sexp)] [hval (xform #t head env)]) (case hval [(syntax) (xform-syntax tail env)] [(quote) (xform-quote tail env)] [(set!) (xform-set! tail env)] [(set&) (xform-set& tail env)] [(if) (xform-if tail env)] [(lambda) (xform-lambda tail env)] [(lambda*) (xform-lambda* tail env)] [(letcc) (xform-letcc tail env)] [(withcc) (xform-withcc tail env)] [(body) (xform-body tail env appos?)] [(begin) (xform-begin tail env)] [(define) (xform-define tail env)] [(define-syntax) (xform-define-syntax tail env)] [(syntax-lambda) (xform-syntax-lambda tail env appos?)] [(syntax-rules) (xform-syntax-rules tail env)] [(syntax-length) (xform-syntax-length tail env)] [(syntax-error) (xform-syntax-error tail env)] [else (if (integrable? hval) (xform-integrable hval tail env) (if (procedure? hval) (xform appos? (hval sexp env) env) (xform-call hval tail env)))]))])) (define (xform-syntax tail env) (if (list1? tail) (car tail) ; must be , todo: check? (x-error "improper syntax form" (cons 'syntax tail)))) (define (xform-quote tail env) (if (list1? tail) (list 'quote (xform-sexp->datum (car tail))) (x-error "improper quote form" (cons 'quote tail)))) (define (xform-ref id env) (let ([den (xenv-ref env id)]) (cond [(eq? (location-val den) '...) (x-error "improper use of ...")] [else (location-val den)]))) (define (xform-set! tail env) (if (and (list2? tail) (id? (car tail))) (let ([den (xenv-lookup env (car tail) 'set!)] [xexp (xform #f (cadr tail) env)]) (if (location-special? den) ;; was (location-set-val! den xexp) '(begin) (x-error "set! to macro or integrable identifier" (cons 'set! tail)) (let ([val (location-val den)]) (if (eq? (car val) 'ref) (list 'set! (cadr val) xexp) (x-error "set! is not allowed" (cons 'set! tail)))))) (x-error "improper set! form" (cons 'set! tail)))) (define (xform-set& tail env) (if (list1? tail) (let ([den (xenv-lookup env (car tail) 'set!)]) (if (location-special? den) (x-error "set& of macro or integrable identifier" (cons 'set& tail)) (let ([val (location-val den)]) (if (eq? (car val) 'ref) (list 'set& (cadr val)) (x-error "set& is not allowed" (cons 'set! tail)))))) (x-error "improper set& form" (cons 'set& tail)))) (define (xform-if tail env) (if (list? tail) (let ([xexps (map (lambda (sexp) (xform #f sexp env)) tail)]) (case (length xexps) [(2) (cons 'if (append xexps '((begin))))] [(3) (cons 'if xexps)] [else (x-error "malformed if form" (cons 'if tail))])) (x-error "improper if form" (cons 'if tail)))) (define (xform-call xexp tail env) (if (list? tail) (let ([xexps (map (lambda (sexp) (xform #f sexp env)) tail)]) (if (and (null? xexps) (eq? (car xexp) 'lambda) (null? (cadr xexp))) (caddr xexp) ; ((let () x)) => x (pair* 'call xexp xexps))) (x-error "improper application" (cons xexp tail)))) (define (integrable-argc-match? igt n) (case igt [(#\0) (= n 0)] [(#\1) (= n 1)] [(#\2) (= n 2)] [(#\3) (= n 3)] [(#\p) (>= n 0)] [(#\m) (>= n 1)] [(#\c) (>= n 2)] [(#\x) (>= n 1)] [(#\u) (<= 0 n 1)] [(#\b) (<= 1 n 2)] [(#\t) (<= 2 n 3)] [(#\#) (>= n 0)] [(#\@) #f] [else #f])) (define (xform-integrable ig tail env) (if (integrable-argc-match? (integrable-type ig) (length tail)) (cons 'integrable (cons ig (map (lambda (sexp) (xform #f sexp env)) tail))) (xform-call (list 'ref (integrable-global ig)) tail env))) (define (xform-lambda tail env) (if (and (list1+? tail) (idslist? (car tail))) (let loop ([vars (car tail)] [ienv env] [ipars '()]) (cond [(pair? vars) (let* ([var (car vars)] [nvar (gensym (id->sym var))]) (loop (cdr vars) (add-local-var var nvar ienv) (cons nvar ipars)))] [(null? vars) (list 'lambda (reverse ipars) (xform-body (cdr tail) ienv #f))] [else ; improper (let* ([var vars] [nvar (gensym (id->sym var))] [ienv (add-local-var var nvar ienv)]) (list 'lambda (append (reverse ipars) nvar) (xform-body (cdr tail) ienv #f)))])) (x-error "improper lambda body" (cons 'lambda tail)))) (define (xform-lambda* tail env) (if (list? tail) (cons 'lambda* (map (lambda (aexp) (if (and (list2? aexp) (or (and (list2? (car aexp)) (fixnum? (caar aexp)) (boolean? (cadar aexp))) (idslist? (car aexp)))) (list (normalize-arity (car aexp)) (xform #f (cadr aexp) env)) (x-error "improper lambda* clause" aexp))) tail)) (x-error "improper lambda* form" (cons 'lambda* tail)))) (define (xform-letcc tail env) (if (and (list2+? tail) (id? (car tail))) (let* ([var (car tail)] [nvar (gensym (id->sym var))]) (list 'letcc nvar (xform-body (cdr tail) (add-local-var var nvar env) #f))) (x-error "improper letcc form" (cons 'letcc tail)))) (define (xform-withcc tail env) (if (list2+? tail) (list 'withcc (xform #f (car tail) env) (xform-body (cdr tail) env) #f) (x-error "improper withcc form" (cons 'withcc tail)))) (define (xform-body tail env appos?) (cond [(null? tail) (list 'begin)] [(list1? tail) ; can't have defines there (xform appos? (car tail) env)] [(not (list? tail)) (x-error "improper body form" (cons 'body tail))] [else (let loop ([env env] [ids '()] [inits '()] [nids '()] [body tail]) (if (and (pair? body) (pair? (car body))) (let ([first (car body)] [rest (cdr body)]) (let* ([head (car first)] [tail (cdr first)] [hval (xform #t head env)]) (case hval [(begin) ; internal (if (list? tail) (loop env ids inits nids (append tail rest)) (x-error "improper begin form" first))] [(define) ; internal (cond [(and (list2? tail) (null? (car tail))) ; idless (let ([init (cadr tail)]) (loop env (cons #f ids) (cons init inits) (cons #f nids) rest))] [(and (list2? tail) (id? (car tail))) (let* ([id (car tail)] [init (cadr tail)] [nid (gensym (id->sym id))] [env (add-local-var id nid env)]) (loop env (cons id ids) (cons init inits) (cons nid nids) rest))] [(and (list2+? tail) (pair? (car tail)) (id? (caar tail)) (idslist? (cdar tail))) (let* ([id (caar tail)] [lambda-id (new-id 'lambda (make-location 'lambda) #f)] [init (cons lambda-id (cons (cdar tail) (cdr tail)))] [nid (gensym (id->sym id))] [env (add-local-var id nid env)]) (loop env (cons id ids) (cons init inits) (cons nid nids) rest))] [else (x-error "improper define form" first)])] [(define-syntax) ; internal (if (and (list2? tail) (id? (car tail))) (let* ([id (car tail)] [init (cadr tail)] [env (extend-xenv-local id '(undefined) env)]) (loop env (cons id ids) (cons init inits) (cons #t nids) rest)) (x-error "improper define-syntax form" first))] [else (if (procedure? hval) (loop env ids inits nids (cons (hval first env) rest)) (xform-labels (reverse ids) (reverse inits) (reverse nids) body env appos?))]))) (xform-labels (reverse ids) (reverse inits) (reverse nids) body env appos?)))])) (define (xform-labels ids inits nids body env appos?) (define no-defines? (andmap (lambda (nid) (eq? nid #t)) nids)) (let loop ([ids ids] [inits inits] [nids nids] [sets '()] [lids '()]) (cond [(null? ids) (if (and no-defines? (list1? body)) ; special case: expand body using current appos? (xform appos? (car body) env) ; general case: produce expression (let* ([xexps (append (reverse sets) (map (lambda (x) (xform #f x env)) body))] [xexp (if (list1? xexps) (car xexps) (cons 'begin xexps))]) (if (null? lids) xexp (pair* 'call (list 'lambda (reverse lids) xexp) (map (lambda (lid) '(begin)) lids)))))] [(not (car ids)) ; idless define, nid is #f (loop (cdr ids) (cdr inits) (cdr nids) (cons (xform #f (car inits) env) sets) lids)] [(symbol? (car nids)) ; define (loop (cdr ids) (cdr inits) (cdr nids) (cons (xform-set! (list (car ids) (car inits)) env) sets) (cons (car nids) lids))] [else ; define-syntax, nid is #t (location-set-val! (xenv-lookup env (car ids) 'set!) (xform #t (car inits) env)) (loop (cdr ids) (cdr inits) (cdr nids) sets lids)]))) (define (xform-begin tail env) ; non-internal (if (list? tail) (let ([xexps (map (lambda (sexp) (xform #f sexp env)) tail)]) (if (and (pair? xexps) (null? (cdr xexps))) (car xexps) ; (begin x) => x (cons 'begin xexps))) (x-error "improper begin form" (cons 'begin tail)))) (define (xform-define tail env) ; non-internal (cond [(and (list2? tail) (null? (car tail))) ; idless (xform #f (cadr tail) env)] [(and (list2? tail) (id? (car tail))) (list 'define (id->sym (car tail)) (xform #f (cadr tail) env))] [(and (list2+? tail) (pair? (car tail)) (id? (caar tail)) (idslist? (cdar tail))) (list 'define (id->sym (caar tail)) (xform-lambda (cons (cdar tail) (cdr tail)) env))] [else (x-error "improper define form" (cons 'define tail))])) (define (xform-define-syntax tail env) ; non-internal (if (and (list2? tail) (id? (car tail))) (list 'define-syntax (id->sym (car tail)) (xform #t (cadr tail) env)) (x-error "improper define-syntax form" (cons 'define-syntax tail)))) (define (xform-syntax-lambda tail env appos?) (if (and (list2+? tail) (andmap id? (car tail))) (let ([vars (car tail)] [macenv env] [forms (cdr tail)]) ; return a transformer that wraps xformed body in (syntax ...) ; to make sure xform treats it as final form and exits the loop (lambda (use useenv) (if (and (list1+? use) (fx=? (length vars) (length (cdr use)))) (let loop ([vars vars] [exps (cdr use)] [env macenv]) (if (null? vars) (list 'syntax (xform-body forms env appos?)) (loop (cdr vars) (cdr exps) (extend-xenv-local (car vars) (xform #t (car exps) useenv) env)))) (x-error "invalid syntax-lambda application" use)))) (x-error "improper syntax-lambda body" (cons 'syntax-lambda tail)))) (define (xform-syntax-rules tail env) (cond [(and (list2+? tail) (id? (car tail)) (andmap id? (cadr tail))) (syntax-rules* env (car tail) (cadr tail) (cddr tail))] [(and (list1+? tail) (andmap id? (car tail))) (syntax-rules* env #f (car tail) (cdr tail))] [else (x-error "improper syntax-rules form" (cons 'syntax-rules tail))])) (define (xform-syntax-length tail env) (if (and (list1? tail) (list? (car tail))) (list 'quote (length (car tail))) (x-error "improper syntax-length form" (cons 'syntax-length tail)))) (define (xform-syntax-error tail env) (let ([args (map xform-sexp->datum tail)]) (if (and (list1+? args) (string? (car args))) (apply x-error args) (x-error "improper syntax-error form" (cons 'syntax-error tail))))) ; make transformer procedure from the rules (define (syntax-rules* mac-env ellipsis pat-literals rules) (define (pat-literal? id) (memq id pat-literals)) (define (not-pat-literal? id) (not (pat-literal? id))) (define (ellipsis-pair? x) (and (pair? x) (ellipsis? (car x)))) (define (ellipsis-denotation? den) (eq? (location-val den) '...)) ; fixme: need eq? with correct #&... (define (ellipsis? x) (if ellipsis (eq? x ellipsis) (and (id? x) (ellipsis-denotation? (xenv-ref mac-env x))))) ; List-ids returns a list of the non-ellipsis ids in a ; pattern or template for which (pred? id) is true. If ; include-scalars is false, we only include ids that are ; within the scope of at least one ellipsis. (define (list-ids x include-scalars pred?) (let collect ([x x] [inc include-scalars] [l '()]) (cond [(id? x) (if (and inc (pred? x)) (cons x l) l)] [(vector? x) (collect (vector->list x) inc l)] [(pair? x) (if (ellipsis-pair? (cdr x)) (collect (car x) #t (collect (cddr x) inc l)) (collect (car x) inc (collect (cdr x) inc l)))] [else l]))) ; Returns #f or an alist mapping each pattern var to a part of ; the input. Ellipsis vars are mapped to lists of parts (or ; lists of lists ...). (define (match-pattern pat use use-env) (call-with-current-continuation (lambda (return) (define (fail) (return #f)) (let match ([pat pat] [sexp use] [bindings '()]) (define (continue-if condition) (if condition bindings (fail))) (cond [(id? pat) (if (pat-literal? pat) (continue-if (and (id? sexp) (eq? (xenv-ref use-env sexp) (xenv-ref mac-env pat)))) (cons (cons pat sexp) bindings))] [(vector? pat) (or (vector? sexp) (fail)) (match (vector->list pat) (vector->list sexp) bindings)] [(not (pair? pat)) (continue-if (equal? pat sexp))] [(ellipsis-pair? (cdr pat)) (let* ([tail-len (length (cddr pat))] [sexp-len (if (list? sexp) (length sexp) (fail))] [seq-len (fx- sexp-len tail-len)] [sexp-tail (begin (if (negative? seq-len) (fail)) (list-tail sexp seq-len))] [seq (reverse (list-tail (reverse sexp) tail-len))] [vars (list-ids (car pat) #t not-pat-literal?)]) (define (match1 sexp) (map cdr (match (car pat) sexp '()))) (append (apply map (cons list (cons vars (map match1 seq)))) (match (cddr pat) sexp-tail bindings)))] [(pair? sexp) (match (car pat) (car sexp) (match (cdr pat) (cdr sexp) bindings))] [else (fail)]))))) (define (expand-template pat tmpl top-bindings) ; New-literals is an alist mapping each literal id in the ; template to a fresh id for inserting into the output. It ; might have duplicate entries mapping an id to two different ; fresh ids, but that's okay because when we go to retrieve a ; fresh id, assq will always retrieve the first one. (define new-literals (body (define nl (map (lambda (id) (cons id (new-id (id->sym id) (xenv-ref mac-env id) (lambda () nl)))) (list-ids tmpl #t (lambda (id) (not (assq id top-bindings)))))) nl)) (define ellipsis-vars (list-ids pat #f not-pat-literal?)) (define (list-ellipsis-vars subtmpl) (list-ids subtmpl #t (lambda (id) (memq id ellipsis-vars)))) (let expand ([tmpl tmpl] [bindings top-bindings]) (let expand-part ([tmpl tmpl]) (cond [(id? tmpl) (cdr (or (assq tmpl bindings) (assq tmpl top-bindings) (assq tmpl new-literals)))] [(vector? tmpl) (list->vector (expand-part (vector->list tmpl)))] [(and (pair? tmpl) (ellipsis-pair? (cdr tmpl))) (let ([vars-to-iterate (list-ellipsis-vars (car tmpl))]) (define (lookup var) (cdr (assq var bindings))) (define (expand-using-vals . vals) (expand (car tmpl) (map cons vars-to-iterate vals))) (if (null? vars-to-iterate) ; ellipsis following non-repeatable part is an error, but we don't care (cons (expand-part (car tmpl)) (expand-part (cddr tmpl))) ; repeat once ; correct use of ellipsis (let ([val-lists (map lookup vars-to-iterate)]) (append (apply map (cons expand-using-vals val-lists)) (expand-part (cddr tmpl))))))] [(pair? tmpl) (cons (expand-part (car tmpl)) (expand-part (cdr tmpl)))] [else tmpl])))) (lambda (use use-env) (let loop ([rules rules]) (if (null? rules) (x-error "invalid syntax" use)) (let* ([rule (car rules)] [pat (car rule)] [tmpl (cadr rule)]) (cond [(match-pattern pat use use-env) => (lambda (bindings) (expand-template pat tmpl bindings))] [else (loop (cdr rules))]))))) ; hand-made transformers (use functionality defined below) (define (make-include-transformer ci?) (define begin-id (new-id 'begin (make-location 'begin) #f)) (lambda (sexp env) (if (list1+? sexp) (let loop ([files (cdr sexp)] [exp-lists '()]) (if (null? files) (cons begin-id (apply append (reverse! exp-lists))) (call-with-file/lib-sexps (car files) ci? ;=> (lambda (exp-list) (loop (cdr files) (cons exp-list exp-lists)))))) (x-error "invalid syntax" sexp)))) (define (if-feature-available-transformer sexp env) (if (and (list? sexp) (= (length sexp) 4)) (let ([r (cadr sexp)] [con (caddr sexp)] [alt (cadddr sexp)]) (if (feature-available? (xform-sexp->datum r)) con alt)) (x-error "invalid syntax" sexp))) (define (if-library-available-transformer sexp env) (if (and (list? sexp) (= (length sexp) 4)) (let ([r (cadr sexp)] [con (caddr sexp)] [alt (cadddr sexp)]) (if (library-available? (xform-sexp->datum r)) con alt)) (x-error "invalid syntax" sexp))) ;--------------------------------------------------------------------------------------------- ; String representation of S-expressions and code arguments ;--------------------------------------------------------------------------------------------- (define (write-serialized-char x port) (cond [(or (char=? x #\%) (char=? x #\") (char=? x #\\) (char? x #\~)) (write-char #\% port) (let ([s (fixnum->string (char->integer x) 16)]) (if (fx=? (string-length s) 1) (write-char #\0 port)) (write-string s port))] [else (write-char x port)])) (define (write-serialized-byte x port) (let ([s (fixnum->string x 16)]) (if (fx=? (string-length s) 1) (write-char #\0 port)) (write-string s port))) (define (write-serialized-size n port) (write-string (fixnum->string n 10) port) (write-char #\: port)) (define (write-serialized-element x port) (write-serialized-sexp x port) (write-char #\; port)) (define (write-serialized-sexp x port) (cond [(eq? x #f) (write-char #\f port)] [(eq? x #t) (write-char #\t port)] [(eq? x '()) (write-char #\n port)] [(char? x) (write-char #\c port) (write-serialized-char x port)] [(number? x) (write-char (if (exact? x) #\i #\j) port) (write-string (number->string x 10) port)] [(list? x) (write-char #\l port) (write-serialized-size (length x) port) (do ([x x (cdr x)]) [(null? x)] (write-serialized-element (car x) port))] [(pair? x) (write-char #\p port) (write-serialized-element (car x) port) (write-serialized-element (cdr x) port)] [(vector? x) (write-char #\v port) (write-serialized-size (vector-length x) port) (do ([i 0 (fx+ i 1)]) [(fx=? i (vector-length x))] (write-serialized-element (vector-ref x i) port))] [(string? x) (write-char #\s port) (write-serialized-size (string-length x) port) (do ([i 0 (fx+ i 1)]) [(fx=? i (string-length x))] (write-serialized-char (string-ref x i) port))] [(bytevector? x) (write-char #\b port) (write-serialized-size (bytevector-length x) port) (do ([i 0 (fx+ i 1)]) [(fx=? i (bytevector-length x))] (write-serialized-byte (bytevector-u8-ref x i) port))] [(symbol? x) (write-char #\y port) (let ([x (symbol->string x)]) (write-serialized-size (string-length x) port) (do ([i 0 (fx+ i 1)]) [(fx=? i (string-length x))] (write-serialized-char (string-ref x i) port)))] [(box? x) (write-char #\z port) (write-serialized-element (unbox x) port)] [else (c-error "cannot encode literal" x)])) (define (write-serialized-arg arg port) (if (and (number? arg) (exact? arg) (fx<=? 0 arg) (fx<=? arg 9)) (write-char (string-ref "0123456789" arg) port) (begin (write-char #\( port) (write-serialized-sexp arg port) (write-char #\) port)))) ;--------------------------------------------------------------------------------------------- ; Compiler producing serialized code ;--------------------------------------------------------------------------------------------- (define (c-error msg . args) (error* (string-append "compiler: " msg) args)) (define (c-warning msg . args) (warning* (string-append "compiler: " msg) args)) (define find-free* (lambda (x* b) (if (null? x*) '() (set-union (find-free (car x*) b) (find-free* (cdr x*) b))))) (define find-free (lambda (x b) (record-case x [quote (obj) '()] [(ref const) (id) (if (set-member? id b) '() (list id))] [set! (id exp) (set-union (if (set-member? id b) '() (list id)) (find-free exp b))] [set& (id) (if (set-member? id b) '() (list id))] [lambda (idsi exp) (find-free exp (set-union (flatten-idslist idsi) b))] [lambda* clauses (find-free* (map cadr clauses) b)] [letcc (kid exp) (find-free exp (set-union (list kid) b))] [withcc (kexp exp) (set-union (find-free kexp b) (find-free exp b))] [if (test then else) (set-union (find-free test b) (set-union (find-free then b) (find-free else b)))] [begin exps (find-free* exps b)] [integrable (ig . args) (find-free* args b)] [call (exp . args) (set-union (find-free exp b) (find-free* args b))] [asm (cstr) '()] [(define define-syntax) tail (c-error "misplaced definition form" x)]))) (define find-sets* (lambda (x* v) (if (null? x*) '() (set-union (find-sets (car x*) v) (find-sets* (cdr x*) v))))) (define find-sets (lambda (x v) (record-case x [quote (obj) '()] [(ref const) (id) '()] [set! (id x) (set-union (if (set-member? id v) (list id) '()) (find-sets x v))] [set& (id) (if (set-member? id v) (list id) '())] [lambda (idsi exp) (find-sets exp (set-minus v (flatten-idslist idsi)))] [lambda* clauses (find-sets* (map cadr clauses) v)] [letcc (kid exp) (find-sets exp (set-minus v (list kid)))] [withcc (kexp exp) (set-union (find-sets kexp v) (find-sets exp v))] [begin exps (find-sets* exps v)] [if (test then else) (set-union (find-sets test v) (set-union (find-sets then v) (find-sets else v)))] [integrable (ig . args) (find-sets* args v)] [call (exp . args) (set-union (find-sets exp v) (find-sets* args v))] [asm (cstr) '()] [(define define-syntax) tail (c-error "misplaced definition form" x)]))) (define codegen ; x: Scheme Core expression to compile ; l: local var list (with #f placeholders for nonvar slots) ; f: free var list ; s: set! var set ; g: global var set ; k: #f: x goes to ac, N: x is to be returned after (sdrop n) ; port: output code goes here (lambda (x l f s g k port) (record-case x [quote (obj) (case obj [(#t) (write-char #\t port)] [(#f) (write-char #\f port)] [(()) (write-char #\n port)] [else (write-char #\' port) (write-serialized-arg obj port)]) (when k (write-char #\] port) (write-serialized-arg k port))] [(ref const) (id) (cond [(posq id l) => ; local (lambda (n) (write-char #\. port) (write-serialized-arg n port) (if (set-member? id s) (write-char #\^ port)))] [(posq id f) => ; free (lambda (n) (write-char #\: port) (write-serialized-arg n port) (if (set-member? id s) (write-char #\^ port)))] [else ; global (write-char #\@ port) (write-serialized-arg id port)]) (when k (write-char #\] port) (write-serialized-arg k port))] [set! (id x) (codegen x l f s g #f port) (cond [(posq id l) => ; local (lambda (n) (write-char #\. port) (write-char #\! port) (write-serialized-arg n port))] [(posq id f) => ; free (lambda (n) (write-char #\: port) (write-char #\! port) (write-serialized-arg n port))] [else ; global (write-char #\@ port) (write-char #\! port) (write-serialized-arg id port)]) (when k (write-char #\] port) (write-serialized-arg k port))] [set& (id) (cond [(posq id l) => ; local (lambda (n) (write-char #\. port) (write-serialized-arg n port))] [(posq id f) => ; free (lambda (n) (write-char #\: port) (write-serialized-arg n port))] [else ; global (write-char #\` port) (write-serialized-arg id port)]) (when k (write-char #\] port) (write-serialized-arg k port))] [begin exps (let loop ([xl exps]) (when (pair? xl) (let ([k (if (pair? (cdr xl)) #f k)]) (codegen (car xl) l f s g k port) (loop (cdr xl))))) (when (and k (null? exps)) (write-char #\] port) (write-serialized-arg k port))] [if (test then else) (codegen test l f s g #f port) (write-char #\? port) (write-char #\{ port) (codegen then l f s g k port) (write-char #\} port) (cond [k ; tail call: 'then' arm exits, so br around is not needed (codegen else l f s g k port)] [(equal? else '(begin)) ; non-tail with void 'else' arm ] ; no code needed -- ac retains #f from failed test [else ; non-tail with 'else' expression; needs br (write-char #\{ port) (codegen else l f s g k port) (write-char #\} port)])] [lambda (idsi exp) (let* ([ids (flatten-idslist idsi)] [free (set-minus (find-free exp ids) g)] [sets (find-sets exp ids)]) (do ([free (reverse free) (cdr free)] [l l (cons #f l)]) [(null? free)] ; note: called with empty set! var list ; to make sure no dereferences are generated (codegen (list 'ref (car free)) l f '() g #f port) (write-char #\, port)) (write-char #\& port) (write-serialized-arg (length free) port) (write-char #\{ port) (cond [(list? idsi) (write-char #\% port) (write-serialized-arg (length idsi) port)] [else (write-char #\% port) (write-char #\! port) (write-serialized-arg (idslist-req-count idsi) port)]) (do ([ids ids (cdr ids)] [n 0 (fx+ n 1)]) [(null? ids)] (when (set-member? (car ids) sets) (write-char #\# port) (write-serialized-arg n port))) (codegen exp ids free (set-union sets (set-intersect s free)) g (length ids) port) (write-char #\} port)) (when k (write-char #\] port) (write-serialized-arg k port))] [lambda* clauses (do ([clauses (reverse clauses) (cdr clauses)] [l l (cons #f l)]) [(null? clauses)] (codegen (cadr (car clauses)) l f s g #f port) (write-char #\% port) (write-char #\x port) (write-char #\, port)) (write-char #\& port) (write-serialized-arg (length clauses) port) (write-char #\{ port) (do ([clauses clauses (cdr clauses)] [i 0 (fx+ i 1)]) [(null? clauses)] (let* ([arity (caar clauses)] [cnt (car arity)] [rest? (cadr arity)]) (write-char #\| port) (if rest? (write-char #\! port)) (write-serialized-arg cnt port) (write-serialized-arg i port))) (write-char #\% port) (write-char #\% port) (write-char #\} port) (when k (write-char #\] port) (write-serialized-arg k port))] [letcc (kid exp) (let* ([ids (list kid)] [sets (find-sets exp ids)] [news (set-union (set-minus s ids) sets)]) (cond [k ; tail position with k locals on stack to be disposed of (write-char #\k port) (write-serialized-arg k port) (write-char #\, port) (when (set-member? kid sets) (write-char #\# port) (write-char #\0 port)) ; stack map here: kid on top (codegen exp (cons kid l) f news g (fx+ k 1) port)] [else ; non-tail position (write-char #\$ port) (write-char #\{ port) (write-char #\k port) (write-char #\0 port) (write-char #\, port) (when (set-member? kid sets) (write-char #\# port) (write-char #\0 port)) ; stack map here: kid on top, two-slot frame under it (codegen exp (cons kid (cons #f (cons #f l))) f news g #f port) (write-char #\_ port) (write-serialized-arg 3 port) (write-char #\} port)]))] [withcc (kexp exp) (cond [(memq (car exp) '(quote ref lambda)) ; exp is a constant, return it (codegen exp l f s g #f port) (write-char #\, port) ; stack map after: k on top (codegen kexp (cons #f l) f s g #f port) (write-char #\w port) (write-char #\! port)] [else ; exp is not a constant, thunk it and call it from k (codegen (list 'lambda '() exp) l f s g #f port) (write-char #\, port) ; stack map after: k on top (codegen kexp (cons #f l) f s g #f port) (write-char #\w port)])] [integrable (ig . args) (let ([igty (integrable-type ig)] [igc0 (integrable-code ig 0)]) (case igty [(#\0 #\1 #\2 #\3) ; 1st arg in a, others on stack (do ([args (reverse args) (cdr args)] [l l (cons #f l)]) [(null? args)] (codegen (car args) l f s g #f port) (unless (null? (cdr args)) (write-char #\, port))) (write-string igc0 port)] [(#\p) ; (length args) >= 0 (if (null? args) (let ([igc1 (integrable-code ig 1)]) (write-string igc1 port)) (let ([opc (fx- (length args) 1)]) (do ([args (reverse args) (cdr args)] [l l (cons #f l)]) [(null? args)] (codegen (car args) l f s g #f port) (unless (null? (cdr args)) (write-char #\, port))) (do ([i 0 (fx+ i 1)]) [(fx>=? i opc)] (write-string igc0 port))))] [(#\m) ; (length args) >= 1 (if (null? (cdr args)) (let ([igc1 (integrable-code ig 1)]) (codegen (car args) l f s g #f port) (write-string igc1 port)) (let ([opc (fx- (length args) 1)]) (do ([args (reverse args) (cdr args)] [l l (cons #f l)]) [(null? args)] (codegen (car args) l f s g #f port) (unless (null? (cdr args)) (write-char #\, port))) (do ([i 0 (fx+ i 1)]) [(fx>=? i opc)] (write-string igc0 port))))] [(#\c) ; (length args) >= 2 (let ([opc (fx- (length args) 1)] [args (reverse args)]) (codegen (car args) l f s g #f port) (write-char #\, port) (do ([args (cdr args) (cdr args)] [l (cons #f l) (cons #f (cons #f l))]) [(null? args)] (codegen (car args) l f s g #f port) (unless (null? (cdr args)) (write-char #\, port) (write-char #\, port))) (do ([i 0 (fx+ i 1)]) [(fx>=? i opc)] (unless (fxzero? i) (write-char #\; port)) (write-string igc0 port)))] [(#\x) ; (length args) >= 1 (let ([opc (fx- (length args) 1)]) (do ([args (reverse args) (cdr args)] [l l (cons #f l)]) [(null? args)] (codegen (car args) l f s g #f port) (unless (null? (cdr args)) (write-char #\, port))) (do ([i 0 (fx+ i 1)]) [(fx>=? i opc)] (write-string igc0 port)))] [(#\u) ; 0 <= (length args) <= 1 (if (null? args) (write-string (integrable-code ig 1) port) (codegen (car args) l f s g #f port)) (write-string igc0 port)] [(#\b) ; 1 <= (length args) <= 2 (if (null? (cdr args)) (write-string (integrable-code ig 1) port) (codegen (cadr args) l f s g #f port)) (write-char #\, port) (codegen (car args) (cons #f l) f s g #f port) (write-string igc0 port)] [(#\t) ; 2 <= (length args) <= 3 (if (null? (cddr args)) (write-string (integrable-code ig 1) port) (codegen (caddr args) l f s g #f port)) (write-char #\, port) (codegen (cadr args) (cons #f l) f s g #f port) (write-char #\, port) (codegen (car args) (cons #f (cons #f l)) f s g #f port) (write-string igc0 port)] [(#\#) ; (length args) >= 0 (do ([args (reverse args) (cdr args)] [l l (cons #f l)]) [(null? args)] (codegen (car args) l f s g #f port) (write-char #\, port)) (write-string igc0 port) (write-serialized-arg (length args) port)] [else (c-error "unsupported integrable type" igty)])) (when k (write-char #\] port) (write-serialized-arg k port))] [call (exp . args) (cond [(and (eq? (car exp) 'lambda) (list? (cadr exp)) (fx=? (length args) (length (cadr exp)))) ; let-like call; compile as special lambda + call combo (do ([args (reverse args) (cdr args)] [l l (cons #f l)]) [(null? args)] (codegen (car args) l f s g #f port) (write-char #\, port)) (let* ([ids (cadr exp)] [exp (caddr exp)] [sets (find-sets exp ids)] [news (set-union (set-minus s ids) sets)] [newl (append ids l)]) ; with real names (do ([ids ids (cdr ids)] [n 0 (fx+ n 1)]) [(null? ids)] (when (set-member? (car ids) sets) (write-char #\# port) (write-serialized-arg n port))) (if k (codegen exp newl f news g (fx+ k (length args)) port) (begin (codegen exp newl f news g #f port) (write-char #\_ port) (write-serialized-arg (length args) port))))] [k ; tail call with k elements under arguments (do ([args (reverse args) (cdr args)] [l l (cons #f l)]) [(null? args) (codegen exp l f s g #f port)] (codegen (car args) l f s g #f port) (write-char #\, port)) (write-char #\[ port) (write-serialized-arg k port) (write-serialized-arg (length args) port)] [else ; non-tail call; 'save' puts 2 extra elements on the stack! (write-char #\$ port) (write-char #\{ port) (do ([args (reverse args) (cdr args)] [l (cons #f (cons #f l)) (cons #f l)]) [(null? args) (codegen exp l f s g #f port)] (codegen (car args) l f s g #f port) (write-char #\, port)) (write-char #\[ port) (write-serialized-arg 0 port) (write-serialized-arg (length args) port) (write-char #\} port)])] [asm (cstr) (write-string cstr port) (when k (write-char #\] port) (write-serialized-arg k port))] [(define define-syntax) tail (c-error "misplaced definition form" x)]))) (define (compile-to-string x) (let ([p (open-output-string)]) (codegen x '() '() '() (find-free x '()) #f p) (get-output-string p))) (define (compile-to-thunk-code x) (let ([p (open-output-string)]) (codegen x '() '() '() (find-free x '()) 0 p) (get-output-string p))) ;--------------------------------------------------------------------------------------------- ; Path and file name resolution ;--------------------------------------------------------------------------------------------- (define (path-strip-directory filename) (let loop ([l (reverse (string->list filename))] [r '()]) (cond [(null? l) (list->string r)] [(memv (car l) '(#\\ #\/ #\:)) (list->string r)] [else (loop (cdr l) (cons (car l) r))]))) (define (path-directory filename) (let loop ([l (reverse (string->list filename))]) (cond [(null? l) ""] [(memv (car l) '(#\\ #\/ #\:)) (list->string (reverse l))] [else (loop (cdr l))]))) (define (path-strip-extension filename) ;; improved (let loop ([l (reverse (string->list filename))]) (cond [(null? l) filename] [(eqv? (car l) #\.) (list->string (reverse (cdr l)))] [(memv (car l) '(#\\ #\/ #\:)) filename] [else (loop (cdr l))]))) #;(define (path-extension filename) (let loop ([l (reverse (string->list filename))] [r '()]) (cond [(null? l) ""] [(memv (car l) '(#\\ #\/ #\:)) ""] [(eqv? (car l) #\.) (list->string (cons #\. r))] [else (loop (cdr l) (cons (car l) r))]))) (define (base-path-separator basepath) (let ([l (reverse (string->list basepath))]) (cond [(null? l) #f] [(memv (car l) '(#\\ #\/)) (car l)] [else #f]))) (define (path-relative? filename) (let ([l (string->list filename)]) (cond [(null? l) #f] [(memv (car l) '(#\\ #\/)) #f] [(and (> (length l) 3) (char-alphabetic? (car l)) (eqv? (cadr l) #\:) (eqv? (caddr l) #\\)) #f] [else #t]))) (define (file-resolve-relative-to-base-path filename basepath) (if (and (path-relative? filename) (base-path-separator basepath)) (string-append basepath filename) ; leading . and .. to be resolved by OS filename)) ; hacks for relative file name resolution (define *current-file-stack* '()) (define (current-file) ;=> filename of #f (and (pair? *current-file-stack*) (car *current-file-stack*))) (define (with-current-file filename thunk) (dynamic-wind (lambda () (set! *current-file-stack* (cons filename *current-file-stack*))) thunk (lambda () (set! *current-file-stack* (cdr *current-file-stack*))))) (define (file-resolve-relative-to-current filename) ; => resolved or original filename (if (path-relative? filename) (let ([cf (current-file)]) (if cf (file-resolve-relative-to-base-path filename (path-directory cf)) filename)) filename)) ;--------------------------------------------------------------------------------------------- ; Library names and library file lookup ;--------------------------------------------------------------------------------------------- (define (mangle-symbol->string sym) (define safe '(#\! #\$ #\- #\_ #\=)) (let loop ([lst (string->list (symbol->string sym))] [text '()]) (cond [(null? lst) (list->string (reverse text))] [(or (char-lower-case? (car lst)) (char-numeric? (car lst))) (loop (cdr lst) (cons (car lst) text))] [(memv (car lst) safe) (loop (cdr lst) (cons (car lst) text))] [else ; use % encoding for everything else (let* ([s (number->string (char->integer (car lst)) 16)] [s (if (< (string-length s) 2) (string-append "0" s) s)] [l (cons #\% (string->list (string-downcase s)))]) (loop (cdr lst) (append (reverse l) text)))]))) (define (listname->symbol lib) (define postfix "") (define prefix "lib:/") (define symbol-prefix "/") (define number-prefix "/") (unless (list? lib) (x-error "invalid library name" lib)) (let loop ([lst lib] [parts (list prefix)]) (if (null? lst) (string->symbol (apply string-append (reverse (cons postfix parts)))) (cond [(symbol? (car lst)) (loop (cdr lst) (cons (mangle-symbol->string (car lst)) (cons symbol-prefix parts)))] [(exact-integer? (car lst)) (loop (cdr lst) (cons (number->string (car lst)) (cons number-prefix parts)))] [else (x-error "invalid library name" lib)])))) (define (listname-segment->string s) (cond [(symbol? s) (mangle-symbol->string s)] [(exact-integer? s) (number->string s)] [else (c-error "invalid library name name element" s)])) (define (listname->path listname basepath ext) (define sep (let ([sc (base-path-separator basepath)]) (if sc (string sc) (c-error "library path does not end in separator" basepath)))) (let loop ([l listname] [r '()]) (if (pair? l) (loop (cdr l) (if (null? r) (cons (listname-segment->string (car l)) r) (cons (listname-segment->string (car l)) (cons sep r)))) (file-resolve-relative-to-base-path (string-append* (reverse (cons ext r))) basepath)))) ; hacks for locating library files (define *library-path-list* '()) (define (add-library-path! path) (if (base-path-separator path) (set! *library-path-list* (append *library-path-list* (list path))) (c-error "library path should end in directory separator" path))) (define (find-library-path libname) ;=> name of existing .sld file or #f (let loop ([l *library-path-list*]) (if (null? l) #f (let ([p (listname->path libname (car l) ".sld")]) (if (and p (file-exists? p)) p (loop (cdr l))))))) (define (resolve-input-file/lib-name name) ;=> path (or error is signalled) (define filepath (if (string? name) (file-resolve-relative-to-current name) (find-library-path name))) (if (not filepath) (if (string? name) (c-error "cannot resolve file name to a file:" name) (c-error "cannot resolve library name to a file:" name 'in *library-path-list*))) (if (not (file-exists? filepath)) (c-error "cannot resolve file or library name to an existing file:" name '=> filepath)) filepath) (define (call-with-input-file/lib name ci? proc) ;=> (proc filepath port), called while name is current-file (let ([filepath (resolve-input-file/lib-name name)]) (with-current-file filepath (lambda () (call-with-input-file filepath (lambda (port) (when ci? (set-port-fold-case! port #t)) (proc filepath port))))))) (define (call-with-file/lib-sexps name ci? proc) ;=> (proc sexps), called while name is current-file (call-with-input-file/lib name ci? ;=> (lambda (filepath port) (let loop ([sexps '()]) (let ([s (read-code-sexp port)]) (if (eof-object? s) (proc (reverse! sexps)) (loop (cons s sexps)))))))) (define (for-each-file/lib-sexp proc name ci?) ; proc called while name is current-file (call-with-input-file/lib name ci? ;=> (lambda (filepath port) (let loop () (let ([s (read-code-sexp port)]) (unless (eof-object? s) (proc s) (loop))))))) ; name prefixes (define (fully-qualified-library-prefixed-name lib id) (string->symbol (string-append (symbol->string (listname->symbol lib)) "?" (symbol->string id)))) ;--------------------------------------------------------------------------------------------- ; Environments ;--------------------------------------------------------------------------------------------- ; new lookup procedure for explicit macro environments (define (env-lookup id env at) ;=> location (| #f) (if (procedure? id) ; nonsymbolic ids can't be (re)defined (case at [(ref set!) (old-den id)] [else #f]) (let loop ([env env]) (cond [(pair? env) ; imported: ref-only (if (eq? (caar env) id) (case at [(ref) (cdar env)] [else #f]) (loop (cdr env)))] [(vector? env) ; extendable, keeps imported? flags (let* ([n (vector-length env)] [i (immediate-hash id n)] [al (vector-ref env i)] [p (assq id al)]) (if p ; p is (key loc imported?) (case at [(ref) (cadr p)] [else (if (caddr p) #f (cadr p))]) ; imported can be ref-d only ; implicitly/on demand append integrables and "naked" globals (let ([loc (make-location (or (lookup-integrable id) (list 'ref id)))]) (vector-set! env i (cons (list id loc #f) al)) ; not imported loc)))] [(string? env) ; module prefix = module internals: full access (and (memq at '(ref set! define define-syntax)) (let ([gid (string->symbol (string-append env (symbol->string id)))]) (env-lookup gid *root-environment* 'ref)))] [(procedure? env) (env id at)] [else ; finite env #f])))) ; make explicit root environment (a vector) and fill it (define *root-environment* (make-vector 101 '())) ; use prime number (define (define-in-root-environment! name loc imported?) (let* ([env *root-environment*] [n (vector-length env)] [i (immediate-hash name n)] [al (vector-ref env i)] [p (assq name al)]) (if p (begin (set-car! (cdr p) loc) (set-car! (cddr p) imported?)) (vector-set! env i (cons (list name loc imported?) al))))) ; put handmade ones first! (define-in-root-environment! 'include (make-location (make-include-transformer #f)) #t) (define-in-root-environment! 'include-ci (make-location (make-include-transformer #t)) #t) (define-in-root-environment! 'if-feature-available (make-location if-feature-available-transformer) #t) (define-in-root-environment! 'if-library-available (make-location if-library-available-transformer) #t) ; now put the builtins (lazily) and others (let ([put! (lambda (k loc) (define-in-root-environment! k loc #t))]) (let loop ([l (initial-transformers)]) (if (null? l) 'ok (let ([p (car l)] [l (cdr l)]) (let ([k (car p)] [v (cdr p)]) (cond [(or (symbol? v) (number? v)) (put! k (make-location v)) (loop l)] [(and (pair? v) (eq? (car v) 'syntax-rules)) (body (define (sr-env id at) (env-lookup id *root-environment* at)) (define sr-v (if (id? (cadr v)) (syntax-rules* sr-env (cadr v) (caddr v) (cdddr v)) (syntax-rules* sr-env #f (cadr v) (cddr v)))) (put! k (make-location sr-v)) (loop l))])))))) (define (root-environment id at) (env-lookup id *root-environment* at)) ; standard library environments in alist form (used as import envs) (define *std-lib->alist-env* '()) (for-each (lambda (r) (define (key->lib k) (case k [(w) '(scheme write)] [(t) '(scheme time)] [(p) '(scheme repl)] [(r) '(scheme read)] [(v) '(scheme r5rs)] [(u) '(scheme r5rs-null)] [(d) '(scheme load)] [(z) '(scheme lazy)] [(s) '(scheme process-context)] [(i) '(scheme inexact)] [(f) '(scheme file)] [(e) '(scheme eval)] [(o) '(scheme complex)] [(h) '(scheme char)] [(l) '(scheme case-lambda)] [(x) '(scheme cxr)] [(b) '(scheme base)])) (define (put-loc! e k loc) (let ([p (assq k (cdr e))]) (cond [p (set-cdr! p loc)] [else (set-cdr! e (cons (cons k loc) (cdr e)))]))) (define (get-env! lib) (or (assoc lib *std-lib->alist-env*) (let ([p (cons lib '())]) (set! *std-lib->alist-env* (cons p *std-lib->alist-env*)) p))) (let loop ([name (car r)] [keys (cdr r)]) (cond [(null? keys) ; all go to (repl) (put-loc! (get-env! '(repl)) name (root-environment name 'ref))] [else (put-loc! (get-env! (key->lib (car keys))) name (root-environment name 'ref)) (loop name (cdr keys))]))) '((* v b) (+ v b) (- v b) (... v u b) (/ v b) (< v b) (<= v b) (= v b) (=> v u b) (> v b) (>= v b) (_ b) (abs v b) (and v u b) (append v b) (apply v b) (assoc v b) (assq v b) (assv v b) (begin v u b) (binary-port? b) (boolean=? b) (boolean? v b) (bytevector b) (bytevector-append b) (bytevector-copy b) (bytevector-copy! b) (bytevector-length b) (bytevector-u8-ref b) (bytevector-u8-set! b) (bytevector? b) (caar v b) (cadr v b) (call-with-current-continuation v b) (call-with-port b) (call-with-values v b) (call/cc b) (car v b) (case v u b) (cdar v b) (cddr v b) (cdr v b) (ceiling v b) (char->integer v b) (char-ready? v b) (char<=? v b) (char=? v b) (char>? v b) (char? b) (close-input-port v b) (close-output-port v b) (close-port b) (complex? v b) (cond v u b) (cond-expand b) (cons v b) (current-error-port b) (current-input-port v b) (current-output-port v b) (define v u b) (define-record-type b) (define-syntax v u b) (define-values b) (denominator v b) (do v u b) (dynamic-wind v b) (else v u b) (eof-object b) (eof-object? v b) (eq? v b) (equal? v b) (eqv? v b) (error b) (error-object-irritants b) (error-object-message b) (error-object? b) (even? v b) (exact b) (exact-integer-sqrt b) (exact-integer? b) (exact? v b) (expt v b) (features b) (file-error? b) (floor v b) (floor-quotient b) (floor-remainder b) (floor/ b) (flush-output-port b) (for-each v b) (gcd v b) (get-output-bytevector b) (get-output-string b) (guard b) (if v u b) (include b) (include-ci b) (inexact b) (inexact? v b) (input-port-open? b) (input-port? v b) (integer->char v b) (integer? v b) (lambda v u b) (lcm v b) (length v b) (let v u b) (let* v u b) (let*-values b) (let-syntax v u b) (let-values b) (letrec v u b) (letrec* b) (letrec-syntax v u b) (list v b) (list->string v b) (list->vector v b) (list-copy b) (list-ref v b) (list-set! b) (list-tail v b) (list? v b) (make-bytevector b) (make-list b) (make-parameter b) (make-string v b) (make-vector v b) (map v b) (max v b) (member v b) (memq v b) (memv v b) (min v b) (modulo v b) (negative? v b) (newline v b) (not v b) (null? v b) (number->string v b) (number? v b) (numerator v b) (odd? v b) (open-input-bytevector b) (open-input-string b) (open-output-bytevector b) (open-output-string b) (or v u b) (output-port-open? b) (output-port? v b) (pair? v b) (parameterize b) (peek-char v b) (peek-u8 b) (port? b) (positive? v b) (procedure? v b) (quasiquote v u b) (quote v u b) (quotient v b) (raise b) (raise-continuable b) (rational? v b) (rationalize v b) (read-bytevector b) (read-bytevector! b) (read-char v b) (read-error? b) (read-line b) (read-string b) (read-u8 b) (real? v b) (remainder v b) (reverse v b) (round v b) (set! v b) (set-car! v b) (set-cdr! v b) (square b) (string v b) (string->list v b) (string->number v b) (string->symbol v b) (string->utf8 b) (string->vector b) (string-append v b) (string-copy v b) (string-copy! b) (string-fill! v b) (string-for-each b) (string-length v b) (string-map b) (string-ref v b) (string-set! v b) (string<=? v b) (string=? v b) (string>? v b) (string? v b) (substring v b) (symbol->string v b) (symbol=? b) (symbol? v b) (syntax-error b) (syntax-rules v u b) (textual-port? b) (truncate v b) (truncate-quotient b) (truncate-remainder b) (truncate/ b) (u8-ready? b) (unless b) (unquote v u b) (unquote-splicing v u b) (utf8->string b) (values v b) (vector v b) (vector->list v b) (vector->string b) (vector-append b) (vector-copy b) (vector-copy! b) (vector-fill! v b) (vector-for-each b) (vector-length v b) (vector-map b) (vector-ref v b) (vector-set! v b) (vector? v b) (when b) (with-exception-handler b) (write-bytevector b) (write-char v b) (write-string b) (write-u8 b) (zero? v b) (case-lambda l) (char-alphabetic? v h) (char-ci<=? v h) (char-ci=? v h) (char-ci>? v h) (char-downcase v h) (char-foldcase h) (char-lower-case? v h) (char-numeric? v h) (char-upcase v h) (char-upper-case? v h) (char-whitespace? v h) (digit-value h) (string-ci<=? v h) (string-ci=? v h) (string-ci>? v h) (string-downcase h) (string-foldcase h) (string-upcase h) (angle v o) (imag-part v o) (magnitude v o) (make-polar v o) (make-rectangular v o) (real-part v o) (caaar v x) (caadr v x) (cadar v x) (caddr v x) (cdaar v x) (cdadr v x) (cddar v x) (cdddr v x) (caaaar v x) (caaadr v x) (caadar v x) (caaddr v x) (cadaar v x) (cadadr v x) (caddar v x) (cadddr v x) (cdaaar v x) (cdaadr v x) (cdadar v x) (cdaddr v x) (cddaar v x) (cddadr v x) (cdddar v x) (cddddr v x) (environment e) (eval v e) (call-with-input-file v f) (call-with-output-file v f) (delete-file f) (file-exists? f) (open-binary-input-file f) (open-binary-output-file f) (open-input-file v f) (open-output-file v f) (with-input-from-file v f) (with-output-to-file v f) (acos v z i) (asin v z i) (atan v z i) (cos v z i) (exp v z i) (finite? z i) (infinite? i) (log v i) (nan? i) (sin v i) (sqrt v i) (tan v i) (delay v u z) (delay-force z) (force v z) (make-promise z) (promise? z) (load v d) (command-line s) (emergency-exit s) (exit s) (get-environment-variable s) (get-environment-variables s) (display w v) (exact->inexact v) (inexact->exact v) (interaction-environment p v) (null-environment v) (read r v) (scheme-report-environment v) (write w v) (current-jiffy t) (current-second t) (jiffies-per-second t) (write-shared w) (write-simple w) ; skint extras go into (repl) only - not to be confused with (scheme repl) (box?) (box) (unbox) (set-box!) )) (define (std-lib->alist-env lib) (cond [(assoc lib *std-lib->alist-env*) => cdr] [else #f])) (define (std-lib->env lib) (cond [(std-lib->alist-env lib) => (lambda (al) (lambda (id at) (and (eq? at 'ref) (let ([p (assq id al)]) (if p (cdr p) #f)))))] [else #f])) ; combine explicit finite env1 with finite or infinite env2 ; env1 here is a proper alist of bindings (( . ) ...) ; env2 can be any environment -- explicit or implicit, finite or not (define (adjoin-env env1 env2) ;=> env12 (if (null? env1) env2 (let ([env2 (adjoin-env (cdr env1) env2)]) (cond [(env-lookup (caar env1) env2 'ref) => (lambda (loc) ; ? loc is not auto-mapped even when env2 supports it (if (eq? (cdar env1) loc) env2 ; repeat of same id with same binding is allowed (c-error "multiple identifier bindings on import:" (caar env1) (cdar env1) loc)))] [else (cons (car env1) env2)])))) ; this variant is used in repl; it allows shadowing of old bindings with new ones ; todo: remove duplicates by starting ; with the env1 and appending non-duplicate parts of env2 (define (adjoin-env/shadow env1 env2) ;=> env12 (if (null? env1) env2 (let ([env2 (adjoin-env/shadow (cdr env1) env2)]) (cond [(env-lookup (caar env1) env2 'ref) => (lambda (loc) ; ? loc is not auto-mapped even when env2 supports it (if (eq? (cdar env1) a) env2 ; repeat of same id with same binding is allowed (begin (c-warning "old identifier binding shadowed on import:" (caar env1) 'was: a 'now: (cdar env1)) (cons (car env1) env2))))] [else (cons (car env1) env2)])))) ; local environment is made for expansion of thislib library's body forms ; it is made of explicit import environment followed by a view to lib-specific ; global locations in root environment, normally prefixed with library name ; NB: import-env is expected to be explicit and limited (just an alist) (define (make-local-env esps thislib import-env) ;=> env (infinite) (let loop ([esps esps] [env import-env]) (if (null? esps) (if (lib-public? thislib) ; all non-exported definitions are public and in global namespace under their own names (append env #t) ; unprefixed view into global namespace (limited use) ; otherwise they are in global namespace under mangled names (append env (fully-qualified-library-prefix thislib))) (loop (cdr esps) ; just for syntax checking (sexp-case (car esps) [ env] [(rename ) env] [else (c-error "invalid export spec in export:" (car esps))]))))) ; environment for import from thislib library into outside libs or programs (define (make-export-env esps thislib import-env) ;=> env (finite, alist) (define (extend-export lid eid env) (cond [(assq eid env) (c-error "duplicate external id in export:" eid esps)] [(assq lid import-env) => ; re-exported imported id, keep using imported binding under eid (lambda (b) (cons (cons eid (cdr b)) env))] [else (cons (cons eid (fully-qualified-library-location thislib lid)) env)])) (if (lib-public? thislib) (if (or esps (pair? import-env)) (c-error "module cannot be imported:" thislib) '()) (let loop ([esps esps] [env '()]) (if (null? esps) env (loop (cdr esps) (sexp-case (car esps) [ (extend-export (car esps) (car esps) env)] [(rename ) (extend-export (cadr (car esps)) (caddr (car esps)) env)] [else (c-error "invalid export spec in export:" (car esps))])))))) ;--------------------------------------------------------------------------------------------- ; Library processing info cache ;--------------------------------------------------------------------------------------------- ; we have to cache loaded libraries, so stores are not hit on repeat loads/visits ; of/to the same library (define *library-info-cache* '()) ;; library info: #(used-libs import-env export-specs beg-forms) (define (make-library-info) (make-vector 4 #f)) (define (library-available? lib) (cond [(assoc lib *library-info-cache*) #t] [(string? lib) (file-resolve-relative-to-current lib)] [(and (pair? lib) (list? lib)) (find-library-path lib)] [else #f])) (define (lookup-library-info lib) ;=> li (possibly non-inited) (cond [(assoc lib *library-info-cache*) => cdr] [(std-lib->alist lib) => (lambda (al) (define li (make-library-info)) (set! *library-info-cache* (cons (cons lib li) *library-info-cache*)) (vector-set! li 0 '()) (vector-set! li 1 al) (vector-set! li 2 (map car al)) (vector-set! li 3 '()) li)] [else (let ([li (make-library-info)]) (set! *library-info-cache* (cons (cons lib li) *library-info-cache*)) li)])) ; main hub for library info -- calls process if library info is not inited (define (get-library-info lib process return) ;=> (return used-libs import-env export-specs beg-forms) (define li (lookup-library-info lib)) (define (update-li! used-libs import-env export-specs beg-forms) (vector-set! li 0 used-libs) (vector-set! li 1 import-env) (vector-set! li 2 export-specs) (vector-set! li 3 beg-forms)) (unless (vector-ref li 0) ; not inited? (call-with-file/lib-sexps lib #f (lambda (all-forms) ; need to split off header forms (process lib all-forms update-li!)))) (return (vector-ref li 0) (vector-ref li 1) (vector-ref li 2) (vector-ref li 3))) ;--------------------------------------------------------------------------------------------- ; Evaluation ;--------------------------------------------------------------------------------------------- ; transformation of top-level form should process begin, define, and define-syntax ; explicitly, so that they can produce and observe side effects on env (define (visit-top-form x env) (if (pair? x) (let ([hval (xform #t (car x) env)]) (cond [(eq? hval 'begin) ; splice (let loop ([x* (cdr x)]) (when (pair? x*) (visit-top-form (car x*) env) (loop (cdr x*))))] [(eq? hval 'define) ; use new protocol for top-level envs (let* ([core (xform-define (cdr x) env)] [loc (xenv-lookup env (cadr core) 'define)]) (if (and loc (sexp-match? '(ref *) (location-val loc))) #t (x-error "identifier cannot be (re)defined in env:" (cadr core) env)))] [(eq? hval 'define-syntax) ; use new protocol for top-level envs (let* ([core (xform-define-syntax (cdr x) env)] [loc (xenv-lookup env (cadr core) 'define-syntax)]) (if loc ; location or #f (location-set-val! loc (caddr core)) ; modifies env! (x-error "identifier cannot be (re)defined as syntax in env:" (cadr core) env)))] [(procedure? hval) ; transformer: apply and loop (visit-top-form (hval x env) env)] [(integrable? hval) ; no env effect possible here #t] [(symbol? hval) ; other specials: no env effect possible here (?? set! ??) #t] [else ; regular call: no env effect possible here #t])) ; var refs and literals : xform for access check #t)) (define (eval-top-form x env) (if (pair? x) (let ([hval (xform #t (car x) env)]) (cond [(eq? hval 'begin) ; splice (let loop ([x* (cdr x)]) (when (pair? x*) (eval-top-form (car x*) env) (loop (cdr x*))))] [(eq? hval 'define) ; use new protocol for top-level envs (let* ([core (xform-define (cdr x) env)] [loc (xenv-lookup env (cadr core) 'define)]) (if (and loc (sexp-match? '(ref *) (location-val loc))) (compile-and-run-core-expr (list 'set! (cadr (location-val loc)) (caddr core))) (x-error "identifier cannot be (re)defined in env:" (cadr core) env)))] [(eq? hval 'define-syntax) ; use new protocol for top-level envs (let* ([core (xform-define-syntax (cdr x) env)] [loc (xenv-lookup env (cadr core) 'define-syntax)]) (if loc ; location or #f (location-set-val! loc (caddr core)) (x-error "identifier cannot be (re)defined as syntax in env:" (cadr core) env)))] [(procedure? hval) ; transformer: apply and loop (eval-top-form (hval x env) env)] [(integrable? hval) ; integrable application (compile-and-run-core-expr (xform-integrable hval (cdr x) env))] [(symbol? hval) ; other specials (compile-and-run-core-expr (xform #f x env))] [else ; regular call (compile-and-run-core-expr (xform-call hval (cdr x) env))])) ; var refs and literals (compile-and-run-core-expr (xform #f x env)))) (define *verbose* #f) (define (compile-and-run-core-expr core) (unless (pair? core) (x-error "unexpected transformed output" core)) (when *verbose* (write core) (newline)) (when (eq? (car core) 'define) (set-car! core 'set!)) (let ([code (compile-to-thunk-code core)]) (when *verbose* (write code) (newline)) (let* ([cl (closure (deserialize-code code))] [r (cl)]) (when *verbose* (write r) (newline))))) (define (visit/v f) (define p (open-input-file f)) (let loop ([x (read-code-sexp p)]) (unless (eof-object? x) (when *verbose* (write x) (newline)) (visit-top-form x root-environment) (when *verbose* (newline)) (loop (read-code-sexp p)))) (close-input-port p)) (define (visit/x f) (define p (open-input-file f)) (let loop ([x (read-code-sexp p)]) (unless (eof-object? x) (when *verbose* (write x) (newline)) (eval-top-form x root-environment) (when *verbose* (newline)) (loop (read-code-sexp p)))) (close-input-port p)) ;--------------------------------------------------------------------------------------------- ; REPL ;--------------------------------------------------------------------------------------------- (define (repl-environment id at) ; FIXME: need to happen in a "repl." namespace (env-lookup id *root-environment* at)) (define (repl-compile-and-run-core-expr core) (when *verbose* (display "TRANSFORM =>") (newline) (write core) (newline)) (unless (pair? core) (x-error "unexpected transformed output" core)) (let ([code (compile-to-thunk-code core)] [start #f]) (when *verbose* (display "COMPILE-TO-STRING =>") (newline) (display code) (newline) (display "DECODE+EXECUTE =>") (newline) (set! start (current-jiffy))) (let* ([cl (closure (deserialize-code code))] [res (cl)]) (when *verbose* (display "Elapsed time: ") (write (* 1000 (/ (- (current-jiffy) start) (jiffies-per-second)))) (display " ms.") (newline)) (unless (eq? res (void)) (write res) (newline))))) (define (repl-eval-top-form x env) (if (pair? x) (let ([hval (xform #t (car x) env)]) (cond [(eq? hval 'begin) ; splice (let loop ([x* (cdr x)]) (when (pair? x*) (repl-eval-top-form (car x*) env) (loop (cdr x*))))] [(and (eq? hval 'define) (null? (cadr x))) ; special idless define (repl-eval-top-form (caddr x) env)] [(eq? hval 'define) ; use new protocol for top-level envs (let* ([core (xform-define (cdr x) env)] [loc (xenv-lookup env (cadr core) 'define)]) (if (and loc (sexp-match? '(ref *) (location-val loc))) (repl-compile-and-run-core-expr (list 'set! (cadr (location-val loc)) (caddr core))) (x-error "identifier cannot be (re)defined in env:" (cadr core) env)))] [(eq? hval 'define-syntax) ; use new protocol for top-level envs (let* ([core (xform-define-syntax (cdr x) env)] [loc (xenv-lookup env (cadr core) 'define-syntax)]) (if loc ; location or #f (location-set-val! loc (caddr core)) (x-error "identifier cannot be (re)defined as syntax in env:" (cadr core) env)) (when *verbose* (display "SYNTAX INSTALLED: ") (write (cadr core)) (newline)))] [(procedure? hval) ; transformer: apply and loop (repl-eval-top-form (hval x env) env)] [(integrable? hval) ; integrable application (repl-compile-and-run-core-expr (xform-integrable hval (cdr x) env))] [(symbol? hval) ; other specials (repl-compile-and-run-core-expr (xform #f x env))] [else ; regular call (repl-compile-and-run-core-expr (xform-call hval (cdr x) env))])) ; var refs and literals (repl-compile-and-run-core-expr (xform #f x env)))) (define (repl-read iport prompt) (when prompt (newline) (display prompt) (display " ")) (read-code-sexp iport)) (define (repl-from-port iport env prompt) (guard (err [(error-object? err) (let ([p (current-error-port)]) (display (error-object-message err) p) (newline p) (for-each (lambda (arg) (write arg p) (newline p)) (error-object-irritants err))) (when prompt (repl-from-port iport env prompt))] [else (let ([p (current-error-port)]) (display "Unknown error:" p) (newline p) (write err p) (newline p)) (when prompt (repl-from-port iport env prompt))]) (let loop ([x (repl-read iport prompt)]) (unless (eof-object? x) (repl-eval-top-form x env) (loop (repl-read iport prompt)))))) (define (repl-file fname env) (define iport (open-input-file fname)) (repl-from-port iport env #f) (close-input-port iport)) (define (benchmark-file fname) (define iport (open-input-file fname)) (unless (sexp-match? '(load "libl.sf") (read-code-sexp iport)) (error "unexpected benchmark file format" fname)) (repl-from-port iport repl-environment #f) (repl-eval-top-form '(main #f) repl-environment) (close-input-port iport)) (define (run-repl) (repl-from-port (current-input-port) repl-environment "skint]"))