;;; This file defines the cig foreign function interface for Scheme 48. ;;; The current version is Cig 3.0. ;;; This file contains the following Scheme 48 modules: ;;; - cig-processor ;;; The code for translating DEFINE-FOREIGN forms into C stubs. ;;; - cig-standalone ;;; The S48 top-level for translating stdin->stdout. ;;; - define-foreign-syntax-support ;;; This package must be opened in the FOR-SYNTAX package, ;;; so that the DEFINE-FOREIGN macro-expander code can use it's procedures. ;;; - define-foreign-syntax ;;; This package must be opened by cig's clients, to access the ;;; DEFINE-FOREIGN and FOREIGN-INCLUDE macros. ;;; ;;; Copyright (c) 1994 by Olin Shivers. (define-structures ((cig-processor (export process-define-foreign-file process-define-foreign-stream)) (cig-standalone (export cig-standalone-toplevel)) ;; This must be opened in the FOR-SYNTAX package. (define-foreign-syntax-support (export define-foreign-expander))) (open scheme formats structure-refs destructuring receiving code-vectors) ; for making alien containers. (access signals) ; for ERROR (begin (define error (structure-ref signals error)) ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;; The general syntax of define-foreign is: ;;; (define-foreign scheme-name (c-name arg1 ... argn) [no-declare] ;;; ret1 ;;; . ;;; retn) ;;; ;;; This defines a Scheme procedure, . It takes the arguments ;;; arg1 ... argn, type-checks them, and then passes them to a C stub, ;;; df_. If the Scheme procedure is to return multiple values, the C ;;; stub also gets a return vector passed to return the extra values. The C ;;; stub rep-converts the Scheme data as specified by the i declarations, ;;; and then calls the C procedure . The C procedure is expected to ;;; return its first value () as its real value. The other return values ;;; are returned by assigning targets passed by-reference to by the ;;; stub. These return parameters are passed after the argument parameters. ;;; When returns, the C stub df_ rep-converts the C data, ;;; stuffs extra return values into the Scheme answer vector if there are any, ;;; and returns to the Scheme routine. The Scheme routine completes the ;;; rep-conversion specified by the i declarations, and return the ;;; values. ;;; ;;; An ARGi spec has the form: ;;; (rep [var]) ;;; where REP gives the representation of the value being passed (see ;;; below), and VAR is the name of the Scheme procedure's parameter (for ;;; documentation purposes, mostly). ;;; ;;; The optional symbol NO-DECLARE means "Do not place an extern declaration ;;; of the C routine in the body of the stub." This is necessary for the ;;; occasional strange ANSI C declaration that cig is incapable of generating ;;; (the only case I know of where the C procedure uses varargs, so the C ;;; declaration needs a ..., e.g., ;;; extern int open(const char *, int flags, ...); ;;; In this case, just use NO-DECLARE, and insert your own a declaration of open() ;;; outside the stub with a ;;; (foreign-source "extern int open(const char *, int flags, ...);") ;;; Ugly, yes.) ;;; ;;; The rep-conversion specs are pretty hairy and baroque. I kept throwing ;;; in machinery until I was able to handle all the Unix syscalls, so that ;;; is what drove the complexity level. See syscalls.scm for examples. ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;; The fields of a rep record for argument reps: ;;; Scheme-pred: ;;; A Scheme predicate for type-testing args. #f means no check. ;;; C-decl: ;;; A C declaration for the argument in its C representation -- ;;; the type of the value actually passed to or returned from the foreign ;;; function. This is a format string; the ~a is where the C variable goes. ;;; (format #f c-decl "") is used to compute a pure type -- e.g., for ;;; casts. ;;; C-cvtr: ;;; The Scheme->C rep-converter; a string. Applied as a C ;;; function/macro in the stub. The empty string means the null ;;; rep-conversion. ;;; Post-C: ;;; Optional post-call processing in the C stub; a string like C-cvtr. ;;; If not #f, this form will be applied in the C stub to the C argument ;;; value *after* the C call returns. It is mostly used to free a ;;; block of storage that was malloc'd by the rep converter on the ;;; way in. (define (argrep:c-decl i) (vector-ref i 0)) (define (argrep:scheme-pred i) (vector-ref i 1)) (define (argrep:c-cvtr i) (vector-ref i 2)) (define (argrep:post-C i) (vector-ref i 3)) ;;; The fields of a rep record for return reps: ;;; C-decl: ;;; As above. ;;; immediate?: ;;; If the return value is to be boxed into a carrier passed in from ;;; Scheme, then this is #f. If this value is a true value, then the ;;; C value is to be rep-converted into an immediate Scheme value. ;;; In this case, the immediate? field is a string, naming the C ;;; function/macro used to do the rep-conversion. ;;; C-boxcvtr: ;;; If immediate? is false, then this value specifies the C code ;;; for rep-converting the return value into the Scheme carrier. ;;; It is a procedure, which is called on two string arguments: ;;; a C variable bound to the carrier, and a C variable bound to ;;; the C return value. The procedure returns a string which is a ;;; C statement for doing the rep-conversion. To pass a raw C value ;;; back, for instance, you would use the following box converter: ;;; (lambda (carrier c-val) (string-append carrier "=" c-val ";")) ;;; make-carrier: ;;; A procedure that when called returns a carrier. This field is only ;;; used if immediate? is #f. This field is a Scheme expression. ;;; S-cvtr ;;; This is a Scheme form that is applied to the rep-converted value passed ;;; back from the C stub. Its value is the actual return value returned to ;;; Scheme. #f means just pass a single value back as-is. This is mostly ;;; used for string hacking. This field is a Scheme expression. (define (retrep:c-decl i) (vector-ref i 0)) (define (retrep:immediate i) (vector-ref i 1)) (define (retrep:C-boxcvtr i) (vector-ref i 2)) (define (retrep:make-carrier i) (vector-ref i 3)) (define (retrep:s-cvtr i) (vector-ref i 4)) ;;; Works for both argrep-info and retrep-info nodes. (define (rep:c-decl i) (vector-ref i 0)) ;;; The Scheme-pred field in this table is a symbol that is syntactically ;;; closed in the macro expander's environment, so the user won't lose ;;; if he should accidentally bind INTEGER? to something unusual, and ;;; then try a DEFINE-FOREIGN. (define *simple-argrep-alist* '( (char #("char ~a" char? "EXTRACT_CHAR" #f)) (bool #("int ~a" #f "EXTRACT_BOOLEAN" #f)) (integer #("int ~a" integer? "EXTRACT_FIXNUM" #f)) (short_u #("unsigned short ~a" integer? "EXTRACT_FIXNUM" #f)) (size_t #("size_t ~a" integer? "EXTRACT_FIXNUM" #f)) (mode_t #("mode_t ~a" integer? "EXTRACT_FIXNUM" #f)) (gid_t #("gid_t ~a" integer? "EXTRACT_FIXNUM" #f)) (uid_t #("uid_t ~a" integer? "EXTRACT_FIXNUM" #f)) (off_t #("off_t ~a" integer? "EXTRACT_FIXNUM" #f)) (pid_t #("pid_t ~a" integer? "EXTRACT_FIXNUM" #f)) (uint_t #("unsigned int ~a" integer? "EXTRACT_FIXNUM" #f)) (long #("long ~a" integer? "EXTRACT_FIXNUM" #f)) (fixnum #("int ~a" fixnum? "EXTRACT_FIXNUM" #f)) (desc #("scheme_value ~a" #f "" #f)) (string-desc #("scheme_value ~a" string? "" #f)) (char-desc #("scheme_value ~a" char? "" #f)) (integer-desc #("scheme_value ~a" integer? "" #f)) (vector-desc #("scheme_value ~a" vector? "" #f)) (pair-desc #("scheme_value ~a" pair? "" #f)) (string #("const char *~a" string? "cig_string_body" #f)) (var-string #("char *~a" string? "cig_string_body" #f)) (string-copy #("char *~a" string? "scheme2c_strcpy" #f)))) ;;; Emit C code to copy a C string into its carrier. (define (str-and-len->carrier carrier str) (format #f "{AlienVal(CAR(~a)) = (long) ~a; CDR(~a) = strlen_or_false(~a);}" carrier str carrier str)) ;;; Carrier and assignment-generator for alien values: (define (simple-assign carrier val) (format #f "AlienVal(~a) = (long) ~a;" carrier val)) ;;; Note: When MAKE-CARRIER and S-CVTR fields are taken from this table, ;;; they are symbols that are syntactically closed in the macro expander's ;;; environment by using the expander's rename procedure. This ensures that ;;; even if the user accidentally binds his own MAKE-ALIEN identifier, ;;; he won't clobber the Scheme stub's use of this MAKE-ALIEN procedure. (define *simple-retrep-alist* `( ;; All the immediate ones (we are sleazing on ints for now). (char #("char ~a" "ENTER_CHAR" #f #f #f)) (bool #("int ~a" "ENTER_BOOLEAN" #f #f #f)) (integer #("int ~a" "ENTER_FIXNUM" #f #f #f)) (fixnum #("int ~a" "ENTER_FIXNUM" #f #f #f)) (short_u #("unsigned short ~a" "ENTER_FIXNUM" #f #f #f)) (size_t #("size_t ~a" "ENTER_FIXNUM" #f #f #f)) (mode_t #("mode_t ~a" "ENTER_FIXNUM" #f #f #f)) (gid_t #("gid_t ~a" "ENTER_FIXNUM" #f #f #f)) (uid_t #("uid_t ~a" "ENTER_FIXNUM" #f #f #f)) (off_t #("off_t ~a" "ENTER_FIXNUM" #f #f #f)) (pid_t #("pid_t ~a" "ENTER_FIXNUM" #f #f #f)) (uint_t #("unsigned int ~a" "ENTER_FIXNUM" #f #f #f)) (long #("long ~a" "ENTER_FIXNUM" #f #f #f)) (desc #("scheme_value ~a" "" #f #f #f)) (string-desc #("scheme_value ~a" "" #f #f #f)) (char-desc #("scheme_value ~a" "" #f #f #f)) (integer-desc #("scheme_value ~a" "" #f #f #f)) (vector-desc #("scheme_value ~a" "" #f #f #f)) (pair-desc #("scheme_value ~a" "" #f #f #f)) (string #("const char *~a" #f ,str-and-len->carrier make-string-carrier string-carrier->string)) (var-string #("char *~a" #f ,str-and-len->carrier make-string-carrier string-carrier->string)) (string-length #("char *~a" "strlen_or_false" #f #f #f)) (static-string #("char *~a" #f ,str-and-len->carrier make-string-carrier string-carrier->string-no-free)))) ;;; String reps: ;;; ----------- ;;; - STRING-COPY ;;; Parameter only. The C routine is given a private, malloc'd C string. ;;; The string is not freed when the routine returns. ;;; ;;; - STRING ;;; Parameter: The C routine is given a C string that it should not alter ;;; or retain beyond the end of the routine. Right now, the Scheme string ;;; is copied to a malloc'd C temporary, which is freed after the routine ;;; returns. Later, we'll just pass a pointer into the actual Scheme ;;; string, as soon as Richard fixes the S48 string reps. ;;; Ret value: The C string is from malloc'd storage. Convert it to a ;;; Scheme string and free the C string. ;;; ;;; - STRING-LENGTH ;;; Return-value only. Return the length of the C string, as a fixnum. ;;; ;;; - STATIC-STRING ;;; Return-value only. The C string is not freed after converting it to ;;; to a Scheme string. ;;; ;;; - VAR-STRING ;;; Same as STRING, but C type is declared char* instead of const char*. ;;; Used to keep some broken system call include files happy. ;;; Parameter reps: ;;; - A simple rep is simply the name of a record in the rep table. ;;; e.g., integer, string ;;; - (REP scheme-pred c-decl to-c [free?]) ;;; A detailed spec, as outlined above. SCHEME-PRED is a procedure or #f. ;;; C-DECL is a format string (or a symbol). TO-C is a format string ;;; (or a symbol). ;;; - (C type) ;;; The argument is a C value, passed with no type-checking ;;; or rep-conversion. TYPE is a format string (or a symbol). ;;; A return-value rep is: ;;; - A simple rep, as above. ;;; - (MULTI-REP rep1 ... repn) ;;; The single value returned from the C function is rep-converted ;;; n ways, each resulting in a distinct return value from Scheme. ;;; - (TO-SCHEME rep c->scheme) ;;; Identical to REP, but use the single C->SCHEME form for the return ;;; rep-conversion in the C stub. There is no POST-SCHEME processing. This ;;; allows you to use a special rep-converter on the C side, but otherwise ;;; use all the properties of some standard rep. C->SCHEME is a string (or ;;; symbol). ;;; - (C type) ;;; Returns a raw C type. No rep-conversion. TYPE is a C type, represented ;;; as a string (or a symbol). ;;; C Short-hand: ;;; Things that go in the C code are usually specified as strings, ;;; since C is case-sensitive, and Scheme symbols are not. However, ;;; as a convenient short-hand, symbols may also be used -- they ;;; are mapped to strings by lower-casing their print names. This ;;; applies to the TO-C part of (REP ...) and the C->SCHEME part of ;;; TO-SCHEME. ;;; ;;; Furthermore, C declarations (the TYPE part of (C ...) and the C-DECL part ;;; of (REP ...)) can be either a format string (e.g., "char ~a[]"), or a ;;; symbol (double). A symbol is converted to a string by lower-casing it, and ;;; appending " ~a", so the symbol double is just convenient short-hand for ;;; the C declaration "double ~a". ;;; ;;; Examples: (rep integer? int "EXTRACT_FIXNUM") ;;; (C char*) ;;; (C "int ~a[10]") ;;; (to-scheme integer "HackInt") ;;; ;;; These shorthand forms are not permitted in the actual rep tables; ;;; only in DEFINE-FOREIGN forms. ;;; Note: the RENAME procedure is for use by the Scheme-stub macro expander ;;; when taking SCHEME-PRED fields from the simple-rep internal table. This ;;; way, the user's bindings of variables won't interfere with the functioning ;;; of the simple reps. When Cig's C-stub generator calls this procedure, it ;;; should just pass the identity procedure for the RENAME argument. (define (parameter-rep->info rep rename) (let* ((hack (lambda (x) (if (symbol? x) (string-append (symbol->string x) " ~a") x))) (do-rep (lambda (scheme-pred C-decl C-cvtr . maybe-post-C) (vector (hack C-decl) scheme-pred (stringify C-cvtr) (and (pair? maybe-post-C) (car maybe-post-C))))) (you-lose (lambda () (error "Unknown parameter rep" rep)))) (cond ((symbol? rep) (cond ((assq rep *simple-argrep-alist*) => (lambda (entry) (let* ((info (copy-vector (cadr entry))) (scheme-pred (argrep:scheme-pred info))) (vector-set! info 1 (and scheme-pred (rename scheme-pred))) info))) (else (you-lose)))) ((pair? rep) (case (car rep) ((rep) (apply do-rep (cdr rep))) ((C) (let* ((c-decl (hack (cadr rep))) (c-type (format #f c-decl ""))) (do-rep (rename 'alien?) c-decl (format #f "(~a)AlienVal" c-type) #f))) (else (you-lose)))) (else (you-lose))))) (define (copy-vector v) (let* ((vlen (vector-length v)) (v-new (make-vector vlen))) (do ((i (- vlen 1) (- i 1))) ((< i 0) v-new) (vector-set! v-new i (vector-ref v i))))) (define (stringify x) (if (symbol? x) (list->string (map char-downcase (string->list (symbol->string x)))) x)) ;;; Fields are as follows: ;;; c-decl: 0, immediate: 1, C-boxcvtr: 2, make-carrier: 3, s-cvtr: 4 ;;; Return a list of reps (because of MULTI-REP). ;;; The RENAME arg is for the Scheme-side macro expander, so that ;;; the make-carrier and s-cvtr fields can be syntactically closed ;;; in the expander's environment. The C-stub generator should just ;;; pass an identity procedure for RENAME. (define (return-rep->info rep rename) (let* ((hack (lambda (x) (if (symbol? x) (string-append (symbol->string x) " ~a") x))) (do-rep (lambda (c-decl . to-scheme) (list (vector (hack c-decl) (list to-scheme) '() #f)))) (you-lose (lambda () (error "Unknown return rep" rep))) (infos (cond ((symbol? rep) (cond ((assq rep *simple-retrep-alist*) => (lambda (entry) ;; Apply RENAME to make-carrier and s-cvtr. (let* ((info (copy-vector (cadr entry))) (make-carrier (retrep:make-carrier info)) (s-cvtr (retrep:s-cvtr info))) (vector-set! info 3 (and make-carrier (rename make-carrier))) (vector-set! info 4 (and s-cvtr (rename s-cvtr))) (list info)))) (else (you-lose)))) ((pair? rep) (case (car rep) ((rep) (let ((v (apply vector rep))) (vector-set! v 0 (hack (vector-ref v 0))) (list v))) ((to-scheme) ; (to-scheme rep converter) (let* ((v (car (return-rep->info (cadr rep) rename))) (v (copy-vector v))) (vector-set! v 1 (stringify (caddr rep))) (vector-set! v 2 '#f) (vector-set! v 3 '#f) (vector-set! v 4 '#f) (list v))) ((C) (list (vector (hack (cadr rep)) #f simple-assign (rename 'make-alien) #f))) ((multi-rep) (apply append (map (lambda (rep) (return-rep->info rep rename)) (cdr rep)))) (else (you-lose)))) (else (you-lose))))) infos)) ;;; Return a type string for IGNORE, or a list of lists of info vectors for ;;; the standard case. (define (parse-return-reps reps rename) (cond ((or (not (pair? reps)) (not (list? reps))) (error "Bad return rep list" reps)) ;; (IGNORE c-type) or IGNORE ((and (null? (cdr reps)) (let ((rep (car reps))) (or (eq? rep 'ignore) (and (pair? rep) (eq? (car rep) 'ignore))))) (let ((rep (car reps))) (if (pair? rep) (cadr rep) "void ~a"))) (else (map (lambda (rep) (return-rep->info rep rename)) reps)))) (define (insert-commas lis) (if (pair? lis) (cdr (let rec ((lis lis)) (if (pair? lis) (cons ", " (cons (car lis) (rec (cdr lis)))) '()))) '(""))) (define (elts->comma-string lis) (apply string-append (insert-commas lis))) (define (info->type i . maybe-outer-type) (let ((outer-type (if (null? maybe-outer-type) "" (car maybe-outer-type)))) (format #f (rep:c-decl i) outer-type))) (define (info->var-decl i var) (format #f "~% ~a;" ; statement-ize decl. (format #f (rep:c-decl i) var))) ; decl-ize var. (define (make-gensym prefix i) (lambda (x) (set! i (+ i 1)) (string-append prefix (number->string i)))) ;;; This returns a list mapping each of the Scheme stub's args to ;;; it's corresponding name in the C stub (e.g., ("arg[2]" "arg[1]" "arg[0]")). ;;; If MV-RETURN? is true, we reserve arg[0] for the mv-return Scheme vec. (define (make-stub-args nargs mv-return?) (do ((i (if mv-return? 1 0) (+ i 1)) (nargs nargs (- nargs 1)) (ans '() (cons (format #f "args[~d]" i) ans))) ((zero? nargs) ans))) (define (filter lis) (if (pair? lis) (let* ((head (car lis)) (tail (cdr lis)) (new-tail (filter tail))) (if head (if (eq? tail new-tail) lis (cons head new-tail)) new-tail)) '())) (define nl (string #\newline)) (define (separate-line stmt) (string-append " " stmt ";" nl)) ;;; Apply a Scheme->C rep-converter to the C expression EXP. (define (C-ize info exp) (cond ((argrep:c-cvtr info) => (lambda (s) (if (string=? s "") exp (string-append s "(" exp ")")))) (else exp))) ;;; Return a C statement rep-converting the C value VAL into the ;;; carrier CARRIER. Rep-conversion is determined by INFO. (define (Scheme-ize->carrier info carrier val) (cond ((retrep:C-boxcvtr info) => (lambda (f) (f carrier val))) (else (error "Rep is not carrier rep:" info)))) ;;; Apply a C->Scheme rep-converter in the C stub to C expression EXP. (define (Scheme-ize-exp converter exp) (if (string=? converter "") exp (string-append converter "(" exp ")"))) ;;; If an arg needs post-C processing in the C stub, ;;; then we need to assign the arg's C rep to a variable. ;;; Return #f or " char *f3 = scm2c_string(arg[2]);" (define (free-var-decl info fvar stub-arg) (and (argrep:post-C info) (format #f "~% ~a = ~a;" (format #f (argrep:c-decl info) fvar) (C-ize info stub-arg)))) ;;; Multiple return values happen across three boundaries: C routine -> C stub, ;;; C stub -> Scheme stub, and Scheme stub -> user. M.v. return happens ;;; across these boundaries sometimes for different reasons. If the ;;; C routine returns m.v., then everyone does. But even if the C routine ;;; returns just a single value, the C stub may rep-convert that multiple ;;; ways, and so need to pass multiple values back to the Scheme stub. ;;; Nomenclature: if someone is returning 4 return values, let's call ;;; the first value returned the *major return value*, and the other three ;;; values the *minor return values*. ;;; M.V. return linkages work like this: ;;; The C routine returns m.v.'s to the C stub by (1) returning the major value ;;; as the value of the C routine, and (2) assigning the minor return values ;;; to pointers passed to the C routine from the stub -- these pointer values ;;; are appended to the routine's parameter list after the actual arguments. ;;; That is, if the C routine needs to return an int, it will be passed ;;; an int*, which it assigns to return the int value. ;;; If the Scheme stub is expecting N multiple values, it passes in ;;; a Scheme vector of size N-1 to the C stub. The C stub stashes the ;;; minor return values into this vector; the major value is passed back ;;; as the C stub's actual return value. This vector is always the last ;;; value passed to the C stub from the Scheme stub, so we can get it ;;; in the C stub by accessing arg[0] or just *arg (remember, the args ;;; get their order reversed during the Scheme/C transition when they ;;; are pushed on the Scheme48 stack, so the m.v. vector, being last, comes ;;; out first). ;;; ;;; If the major return value for the call requires a carrier structure, ;;; it is passed in the m.v. Scheme vector, in the first element of the ;;; vector. The carrier itself is returned as the C stub's major return value. ;;; MAKE-MV-ASSIGNS produces the C code that puts the C stub's minor ;;; return values into the vector. For each value and each rep for that value: ;;; - If the value is the major return value: ;;; + if the value is immediate, it is rep-converted, and assigned to ;;; the variable ret1. ;;; + if the value is passed back in a carrier, the carrier is fetched ;;; from the m.v. vector's elt 0, and the value is rep-converted into ;;; this carrier. The carrier itself is assigned to ret1. ;;; - If the value is a minor return value: ;;; + if the value is immediate, it is rep-converts, and assigned to ;;; the appropriate slot in the m.v. vector. ;;; + if the value is passed back in a carrier, the carrier is fetched ;;; from the m.v. vector, and the value is rep-converted into the carrier. ;;; Ugh. Nested looping in Scheme is like nested looping in assembler. (define (make-mv-assigns c-vars info-lists) (apply string-append (let lp1 ((j 0) ; J is location in Scheme vec into which we store. (c-vars c-vars) (info-lists info-lists) (assigns '())) (if (pair? c-vars) (let ((v (car c-vars)) (info-list (car info-lists)) (c-vars (cdr c-vars)) (info-lists (cdr info-lists))) ;; Loop over V's info elts in INFO-LIST (let lp2 ((j j) (info-list info-list) (assigns assigns)) (if (pair? info-list) ;; Do rep-conversion INFO. (let ((info (car info-list)) (info-list (cdr info-list))) (receive (c-stmt j) (if (null? assigns) (make-major-retval-stmt v info) (make-minor-retval-stmt v info j)) (lp2 j info-list (cons c-stmt assigns)))) (lp1 j c-vars info-lists assigns)))) (reverse assigns))))) ;;; c-decl: 0, immediate: 1, C-boxcvtr: 2, make-carrier: 3, s-cvtr: 4 ;;; Major ret value rep conversion. If immediate, just rep-convert & assign ;;; to ret1. If carrier, store into an alien struct and assign that to ret1. ;;; C-VAR should always be "r1". (define (make-major-retval-stmt c-var info) (cond ((retrep:immediate info) => (lambda (cvtr) (values (format #f "~% ret1 = ~a;" (Scheme-ize-exp cvtr c-var)) 0))) (else (values (format #f "~% ret1 = VECTOR_REF(*args,0);~% ~a" (Scheme-ize->carrier info "ret1" c-var)) 1)))) ;;; Minor ret value rep-conversion. ;;; Convert and store into minor-value vector at entry j. (define (make-minor-retval-stmt c-var info j) (let ((target (format #f "VECTOR_REF(*args,~d)" j))) (values (cond ((retrep:immediate info) => (lambda (cvtr) (format #f "~% ~a = ~a;" target (Scheme-ize-exp cvtr c-var)))) (else (format #f "~% ~a" (Scheme-ize->carrier info target c-var)))) (+ j 1)))) (define (stmts strings) (apply string-append strings)) (define (make-post-C-var-list infos) (do ((j 1 (+ j 1)) (infos infos (cdr infos)) (ans '() (cons (let ((i (car infos))) (and (argrep:post-C i) (format #f "f~d" j))) ans))) ((not (pair? infos)) (reverse ans)))) ;;; Compute the args part of function prototype. (define (proto-args arg-decls) (if (null? arg-decls) "void" ; echh (elts->comma-string arg-decls))) (define (define-foreign->C-stub form) (destructure (( (#f scheme-name (c-name . params) . return-reps) form )) (let* ((c-name (stringify c-name)) (reps (map car params)) (no-declare? (and (pair? return-reps) (eq? 'no-declare (car return-reps)))) (return-reps (if no-declare? (cdr return-reps) return-reps)) (params-info (map (lambda (rep) (parameter-rep->info rep (lambda (x) x))) reps)) ;; A list of lists, due to MULTI-REP. (ret-infos1 (parse-return-reps return-reps (lambda (x) x))) (ignore? (string? ret-infos1)) (ret-infos2 (if (not ignore?) ; Flatten them out. (apply append ret-infos1))) (ret-infos3 (if (not ignore?) ; A canonical representative (map car ret-infos1))) ; per item. (primary-retval-info (if (not ignore?) (car ret-infos3))) (primary-retval-decl-template (if ignore? ret-infos1 (retrep:c-decl primary-retval-info))) ;; The type of the value returned by the C routine, ;; stored into the C stub's r1 variable. (primary-retvar-decl (if ignore? "" (format #f "~% ~a;" (format #f primary-retval-decl-template "r1")))) (mv-return? (and (not ignore?) (or (pair? (cdr ret-infos2)) ;; Is major ret val non-immediate (not (retrep:immediate (caar ret-infos1)))))) (nargs (length reps)) (stub-nargs (if mv-return? (+ nargs 1) nargs)) (other-retvals (if ignore? '() (cdr ret-infos3))) (ret-vars (map (make-gensym "r" 1) other-retvals)) (ret-var-decls (stmts (map info->var-decl other-retvals ret-vars))) ;; List of the form ("arg[2]" "arg[1]" "arg[0]"). (stub-args (make-stub-args nargs mv-return?)) (post-C-vars (make-post-C-var-list params-info)) (pc-var-decls (stmts (map (lambda (i v) (if v (info->var-decl i v) "")) params-info post-C-vars))) (c-proto (proto-args (append (map info->type params-info) (map (lambda (i) (info->type i "*")) other-retvals)))) (c-fun-decl (format #f primary-retval-decl-template (string-append c-name "(" c-proto ")"))) (c-fun-decl (format #f "extern ~a;" c-fun-decl)) (c-fun-decl (if no-declare? "" c-fun-decl)) (pc-var-assigns (stmts (map (lambda (i fv sv) (if fv (format #f "~% ~a = ~a;" fv (C-ize i sv)) "")) params-info post-C-vars stub-args))) (c-args (elts->comma-string (append (map (lambda (i fv sv) (or fv (C-ize i sv))) params-info post-C-vars stub-args) (map (lambda (rv) (string-append "&" rv)) ret-vars)))) (c-call (string-append c-name "(" c-args ")")) ;; Do the post-C-call processing in the C stub. (post-C-val-processing (stmts (map (lambda (v i) (if v (format #f "~% %a(~a);" (argrep:post-C i) v) "")) post-C-vars reps))) (mv-assigns (if ignore? "" (make-mv-assigns (cons "r1" ret-vars) ret-infos1))) (return-stmt (format #f "~% return ~a;" (if ignore? "SCHFALSE" "ret1"))) ;; Do the call, release the free-vars, do the mv-return ;; assignments, then return. (epilog (if ignore? (string-append c-call ";" post-C-val-processing return-stmt) (string-append "r1 = " c-call ";" post-C-val-processing mv-assigns return-stmt)))) ; (breakpoint) (format #f cfun-boilerplate c-name c-fun-decl (if ignore? "" ret1-decl) primary-retvar-decl ret-var-decls pc-var-decls stub-nargs c-name pc-var-assigns epilog)))) (define cfun-boilerplate "scheme_value df_~a(long nargs, scheme_value *args) { ~a~a~a~a~a cig_check_nargs(~d, nargs, \"~a\");~a ~a } ") (define ret1-decl " scheme_value ret1;") ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; (define cfile-header-boilerplate "/* This is an Scheme48/C interface file, ** automatically generated by cig. */ #include #include /* For malloc. */ #include \"libcig.h\" ") (define (define-foreign-process-form form oport) (if (pair? form) (case (car form) ((begin) (if (list? (cdr form)) (for-each (lambda (f) (define-foreign-process-form f oport)) (cdr form)))) ((define-structure define-structures) (if (and (pair? (cdr form)) (list? (cddr form))) (let ((clauses (cddr form))) (for-each (lambda (clause) (if (and (pair? clause) (eq? 'begin (car clause))) (define-foreign-process-form clause oport))) clauses)))) ((define-foreign) (display (define-foreign->C-stub form) oport)) ((foreign-source) (let ((forms (cdr form))) (if (pair? forms) (begin (display (car forms) oport) (map (lambda (x) (newline oport) (display x oport)) (cdr forms))))))))) (define (process-define-foreign-stream iport oport) (display cfile-header-boilerplate oport) (let lp () (let ((form (read iport))) (cond ((not (eof-object? form)) (define-foreign-process-form form oport) (lp)))))) (define (process-define-foreign-file fname) (call-with-input-file (string-append fname ".scm") (lambda (iport) (call-with-output-file (string-append fname ".c") (lambda (oport) (process-define-foreign-stream iport oport)))))) (define (cig-standalone-toplevel . args) ; ignore your args. (process-define-foreign-stream (current-input-port) (current-output-port)) 0) ;;; This section defines the Scheme-side macro processor. ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;; (define-syntax define-foreign define-foreign-expander) (define (define-foreign-expander form rename compare) (destructure (( (#f scheme-name (c-name . params) . return-reps) form )) (let* ((c-name (string-append "df_" (stringify c-name))) (reps (map car params)) (params-info (map (lambda (rep) (parameter-rep->info rep rename)) reps)) (return-reps (if (and (pair? return-reps) (eq? 'no-declare (car return-reps))) (cdr return-reps) return-reps)) (ret-infos1 (parse-return-reps return-reps rename)) (ignore? (string? ret-infos1)) (ret-infos2 (if (not ignore?) (apply append ret-infos1))) (major-rep (and (not ignore?) (car ret-infos2))) ;; Does the Scheme stub return m.v.'s to the user? (scheme-mv-return? (and (not ignore?) (pair? (cdr ret-infos2)))) (carrier-vec? (or scheme-mv-return? (and major-rep (not (retrep:immediate major-rep))))) (carrier-veclen (if carrier-vec? (- (length ret-infos2) (if (retrep:immediate major-rep) 1 0)))) (%define (rename 'define)) (%let (rename 'let)) (%lambda (rename 'lambda)) (%external-call (rename 'external-call)) (%get-external (rename 'get-external)) (gensym (let ((gs (make-gensym "g" -1))) (lambda () (string->symbol (gs #f))))) (args (map (lambda (p) (let ((tail (cdr p))) (if (pair? tail) (car tail) (gensym)))) params)) (%string? (rename 'string?)) (%char? (rename 'char?)) (%integer? (rename 'integer?)) (%vector? (rename 'vector?)) (%pair? (rename 'pair?)) (%check-arg (rename 'check-arg)) (rep-checker (lambda (i arg) (cond ((argrep:scheme-pred i) => (lambda (pred) `(,%check-arg ,pred ,arg ,scheme-name))) (else arg)))) (c-args (map rep-checker params-info args)) (%f (rename 'f))) (if (not carrier-vec?) (let* ((xcall `(,%external-call ,%f ,@c-args)) (xcall (cond ((and (not ignore?) (retrep:s-cvtr (car ret-infos2))) => (lambda (proc) `(,proc ,xcall))) ; not hygenic (else xcall)))) `(,%define ,scheme-name (,%let ((,%f (,%get-external ,c-name))) (,%lambda ,args ,xcall)))) (let ((retarg1 (rename 'r1)) (retarg2 (rename 'r2)) (%make-vector (rename 'make-vector))) `(,%define ,scheme-name (,%let ((,%f (,%get-external ,c-name))) (,%lambda ,args (,%let ((,retarg2 (,%make-vector ,carrier-veclen))) ,@(install-carriers retarg2 ret-infos2 (rename 'vector-set!)) (,%let ((,retarg1 (,%external-call ,%f ,@c-args ,retarg2))) (values ,@(make-values-args retarg1 retarg2 ret-infos2 rename)))))))))))) (define (install-carriers carrier-vec ret-infos2 %vector-set!) ;; Skip the major ret value if it doesn't require a carrier. (let* ((major-rep (and (pair? ret-infos2) (car ret-infos2))) (infos (if (and major-rep (retrep:immediate major-rep)) (cdr ret-infos2) ret-infos2))) (let lp ((ans '()) (infos infos) (i 0)) (if (null? infos) ans (let ((info (car infos)) (infos (cdr infos))) (if (retrep:immediate info) (lp ans infos (+ i 1)) (lp (cons `(,%vector-set! ,carrier-vec ,i (,(retrep:make-carrier info))) ans) infos (+ i 1)))))))) (define (c-arg i retarg1 retarg2 %vector-ref) (if (zero? i) retarg1 `(,%vector-ref ,retarg2 ,(- i 1)))) (define (make-values-args arg1 carrier-vec infos rename) (let ((%vector-ref (rename 'vector-ref)) (do-arg (lambda (arg info) (cond ((retrep:s-cvtr info) => (lambda (cvtr) `(,cvtr ,arg))) (else arg))))) (if (null? infos) '() (let lp ((ans (list (do-arg arg1 (car infos)))) (i (if (retrep:immediate (car infos)) 0 1)) (infos (cdr infos))) (if (pair? infos) (let* ((info (car infos)) (arg `(,%vector-ref ,carrier-vec ,i))) (lp (cons (do-arg arg info) ans) (+ i 1) (cdr infos))) (reverse ans)))))) )) ; egakcap (define-structure define-foreign-syntax (export (define-foreign :syntax) (foreign-source :syntax)) (open scheme externals structure-refs cig-aux) (access signals) ; for ERROR (for-syntax (open scheme define-foreign-syntax-support)) (begin (define error (structure-ref signals error)) (define-syntax define-foreign define-foreign-expander) ;; Ignore FOREIGN-SOURCE forms. (define-syntax foreign-source (syntax-rules () ((foreign-source stuff ...) #f))) (define (check-arg pred obj proc) (if (not (pred obj)) (error "check-arg" pred obj proc) obj)) )) ; egakcap ;;; Todo: "info" terminology is gone. Clean up.