; Copyright (c) 1993, 1994 Richard Kelsey and Jonathan Rees. See file COPYING. ; This is file transport.scm. ; System builder for bootstrapping and debugging. ; Things that have to be written out: ; Made by the compiler ; closures ; templates ; code-vectors ; locations ; Quoted data ; symbols ; pairs ; vectors ; strings ; booleans ; characters ; Convert THING to the Scheme 48 virtual machine's representation and ; return it. Locations and symbols may have multiple references in ; the image. Their transported addresses are kept in a table. (define (transport thing) (let transport ((thing thing)) (cond ((immediate? thing) (transport-immediate thing)) ((closure? thing) (transport-closure thing)) ((code-vector? thing) (allocate-b-vector thing code-vector-length)) ((location? thing) (let ((address (table-ref *locations* thing))) (cond (address address) (else (let ((desc (transport-location thing))) (table-set! *locations* thing desc) desc))))) ((symbol? thing) (let ((address (table-ref *symbols* thing))) (cond (address address) (else (let ((desc (transport-symbol thing))) (table-set! *symbols* thing desc) desc))))) ((pair? thing) (transport-pair thing)) ((template? thing) (transport-template thing)) ((vector? thing) (transport-vector thing)) ((string? thing) (allocate-b-vector thing (lambda (x) (+ 1 (string-length x))))) (else (error "cannot transport object" thing))))) ; Transport the things that are not allocated from the heap. (define (transport-immediate thing) (cond ((integer? thing) (make-descriptor (enum tag fixnum) thing)) ((char? thing) (make-immediate (enum imm char) (char->ascii thing))) ((eq? thing '()) vm-null) ((eq? thing #f) vm-false) ((eq? thing #t) vm-true) ((eq? thing (unspecific)) vm-unspecific) (else (error "cannot transport literal" thing)))) ;============================================================================== ; The heap is a list of transported stored objects, each of which is either a ; string, a code-vector, or a vector of length N+1 representing a stored object ; with N cells. The last slot of the vector is the object's header. (define *heap* '()) (define *hp* 0) ; Current heap-pointer (in a-units) (define *symbols* #f) ; Table of already-transported symbols (define *locations* #f) ; Table of already-transported locations (define (initialize-memory) (set! *hp* 0) (set! *heap* '()) (set! *symbols* (make-table)) (set! *locations* (make-table location-id))) ; Allocate a new stored object in the heap. DATA is whatever data is ; associated with the object, LEN is the length of the object (not ; including the header) in bytes. A pointer to the new object is ; returned. (define (allocate-stob data len) (let ((addr (+ *hp* (cells->a-units 1)))) ; move past header (set! *hp* (+ addr (bytes->a-units len))) (set! *heap* (cons data *heap*)) (make-stob-descriptor addr))) ; Allocate a new stored object that contains descriptors. This ; creates a vector to hold the header and the object's tranported ; contents and allocates a stob in the heap. Returns a pair ; containing the stob-pointer and the vector. (define (allocate-d-vector type cells immutable?) (let* ((vec (make-vector (+ cells 1) 0)) (ptr (allocate-stob vec (cells->bytes cells))) (hdr (make-header type (cells->bytes cells)))) (vector-set! vec cells (if immutable? (make-header-immutable hdr) hdr)) (cons ptr vec))) ; Allocate a new stored object that contains data. VEC is either a ; code-vector or a string. (define (allocate-b-vector vec length) (let ((len (cells->bytes (bytes->cells (length vec))))) (allocate-stob vec len))) ;============================================================================== ; Transport an object with two slots. ALLOCATE-D-VECTOR allocates the ; storage and then the two values are transported. (define (transport-two-slot type accessor1 offset1 accessor2 offset2 immutable?) (lambda (thing) (let* ((data (allocate-d-vector type 2 immutable?)) (descriptor (car data)) (vector (cdr data))) (vector-set! vector offset1 (transport (accessor1 thing))) (vector-set! vector offset2 (transport (accessor2 thing))) descriptor))) ; Closures and pairs are transported using TRANSPORT-TWO-SLOT. (define transport-closure (transport-two-slot (enum stob closure) closure-template closure-template-offset closure-env closure-env-offset #t)) ; *** (define transport-pair (transport-two-slot (enum stob pair) car car-offset cdr cdr-offset #t)) ; *** ? ; Transporting a location requires some care so as to avoid calling CONTENTS ; when the location is unbound. (define (transport-location loc) (let* ((data (allocate-d-vector (enum stob location) 2 #f)) (descriptor (car data)) (vector (cdr data))) (vector-set! vector location-contents-offset (if (location-defined? loc) (transport (contents loc)) vm-unbound)) (vector-set! vector location-id-offset (transport (location-id loc))) descriptor)) ; Symbols have one slot, the string containing the symbol's name. ; Characters in the symbol name are made to be lower case. (define (transport-symbol symbol) (let* ((data (allocate-d-vector (enum stob symbol) 1 #t)) (descriptor (car data)) (vector (cdr data))) (vector-set! vector 0 (transport (symbol-case-converter (symbol->string symbol)))) descriptor)) (define (string-case-converter string) (let ((new (make-string (string-length string) #\x))) (do ((i 0 (+ i 1))) ((>= i (string-length new)) new) (string-set! new i (preferred-case (string-ref string i)))))) ;(define preferred-case ;Copied from rts/read.scm ; (if (char=? (string-ref (symbol->string 't) 0) #\T) ; char-upcase ; char-downcase)) (define preferred-case char-downcase) (define symbol-case-converter (if (char=? (string-ref (symbol->string 't) 0) (preferred-case #\t)) (lambda (string) string) string-case-converter)) ; Templates and vectors have an arbitrary number of slots but are otherwise ; the same as pairs and closures. (define (transport-template template) (transport-vector-like template (enum stob template) (template-length template) template-ref #f)) (define (transport-vector vector) (transport-vector-like vector (enum stob vector) (vector-length vector) vector-ref #t)) ;*** (define (transport-vector-like vector type length ref immutable?) (let* ((data (allocate-d-vector type length immutable?)) (descriptor (car data)) (new (cdr data))) (do ((i 0 (+ i 1))) ((>= i length)) (vector-set! new i (transport (ref vector i)))) descriptor)) ;============================================================================== ; Writing the heap out to a port. (define (write-heap port) (do ((heap (reverse *heap*) (cdr heap))) ((null? heap)) (write-heap-stob (car heap) port))) ; Dispatch on the type of THING and call WRITE-STOB. (define (write-heap-stob thing port) (cond ((string? thing) (let ((len (+ 1 (string-length thing)))) (write-stob (make-header-immutable ; *** (make-header (enum stob string) len)) thing len nulled-string-ref write-char port) (align-port len port))) ((code-vector? thing) (let ((len (code-vector-length thing))) (write-stob (make-header-immutable ; *** (make-header (enum stob code-vector) len)) thing len code-vector-ref write-byte port) (align-port len port))) ((vector? thing) (let ((len (vector-length thing))) (write-stob (vector-ref thing (- len 1)) thing (- len 1) vector-ref write-descriptor port))) (else (error "do not know how to write stob" thing)))) (define (nulled-string-ref string i) (if (= i (string-length string)) (ascii->char 0) (string-ref string i))) ; Write out a transported STOB to PORT. HEADER is the header, LENGTH is the ; number of objects the STOB contains, ACCESSOR and WRITER access the contents ; and write them to the heap. (define (write-stob header contents length accessor writer port) (write-descriptor header port) (do ((i 0 (+ i 1))) ((>= i length)) (writer (accessor contents i) port))) ; Write out zeros to align the port on a four-byte boundary. (define (align-port len port) (let ((count (- (cells->bytes (bytes->cells len)) len))) (do ((count count (- count 1))) ((<= count 0)) (write-byte 0 port))))