;;; Ported from Scheme 48 1.9. See file COPYING for notices and license. ;;; ;;; Port Author: Andrew Whatson ;;; ;;; Original Authors: Richard Kelsey, Jonathan Rees, Mike Sperber, Marcus ;;; Crestani David Frese, Taylor Campbell ;;; ;;; scheme48-1.9.2/scheme/prescheme/memory.scm ;;; ;;; An implementation of Pre-Scheme's memory interface that can detect some ;;; stray reads and writes. It has numerous limitiations: ;;; Allocations are always on page boundaries. ;;; No more than 16 megabytes can be allocated at once. ;;; More than 32 or 64 or so allocations result in addresses being ;;; bignums (dealloctions have no effect on this). ;;; ;;; Memory is represented as a vector of byte-vectors, with each byte-vector ;;; representing a 16-megabyte page. Allocations are always made on page ;;; boundaries, so the byte-vectors only need be as large as the allocated ;;; areas. Pages are never re-used. ;;; ;;; (Scheme 48 still calls byte-vectors code-vectors.) ;;; ;;; ;;; Addresses are distinct from integers. ;;; (define-module (prescheme memory) #:use-module (srfi srfi-9) #:use-module (srfi srfi-9 gnu) #:use-module (prescheme scheme48)) (define-record-type :address (make-address index) address? (index address-index)) (set-record-type-printer! :address (lambda (addr port) (format port "{Address ~a}" (address-index addr)))) ;; We add 100000000 to addresses to make them (define address-offset 100000000) (define (address->integer addr) (+ (address-index addr) address-offset)) (define (integer->address int) (make-address (- int address-offset))) (define (address+ address integer) (make-address (+ (address-index address) integer))) (define (address- address integer) (make-address (- (address-index address) integer))) (define (address-binop op) (lambda (address1 address2) (op (address-index address1) (address-index address2)))) (define address-difference (address-binop -)) (define address= (address-binop =)) (define address< (address-binop <)) (define address<= (address-binop <=)) (define address> (address-binop >)) (define address>= (address-binop >=)) (define null-address (make-address -1)) (define (null-address? address) (address= address null-address)) ;; Memory (define *memory* (make-vector 16 #f)) ;; vector of pages (define log-max-size 25) ;; log of page size (define address-shift (- log-max-size)) ;; turns addresses into page indices (define max-size (arithmetic-shift 1 log-max-size)) ;; page size (define address-mask ;; mask to get address within page (- (arithmetic-shift 1 log-max-size) 1)) (define *next-index* 0) ;; next available page (define (reinitialize-memory) (set! *memory* (make-vector 16 #f)) (set! *next-index* 0)) ;; Extend the page vector if necessary, and then make a page of the ;; appropriate size. (define (allocate-memory size) (cond ((> size max-size) null-address) ;; error result (else (if (>= *next-index* (vector-length *memory*)) (let ((new (make-vector (* 2 (vector-length *memory*))))) (do ((i 0 (+ i 1))) ((>= i (vector-length *memory*))) (vector-set! new i (vector-ref *memory* i))) (set! *memory* new))) (let ((index *next-index*)) (set! *next-index* (+ *next-index* 1)) (vector-set! *memory* index (make-code-vector size 0)) (make-address (arithmetic-shift index log-max-size)))))) ;; Turning an address into a page or page index (define (address->vector address) (vector-ref *memory* (arithmetic-shift address address-shift))) (define (address->vector-index address) (bitwise-and address address-mask)) ;; Throw away the page containing ADDRESS, which must be the first address in ;; that page, (define (deallocate-memory address) (let ((address (address-index address))) (let ((vector (address->vector address)) (byte-address (address->vector-index address))) (if (and vector (= byte-address 0)) (vector-set! *memory* (arithmetic-shift address address-shift) #f) (assertion-violation 'deallocate-memory "bad deallocation address" address))))) ;; Various ways of accessing memory (define (unsigned-byte-ref address) (let ((address (address-index address))) (code-vector-ref (address->vector address) (address->vector-index address)))) (define (signed-code-vector-ref bvec i) (let ((x (code-vector-ref bvec i))) (if (< x 128) x (bitwise-ior x -128)))) (define (word-ref address) (let ((address (address-index address))) (let ((vector (address->vector address)) (byte-address (address->vector-index address))) (if (not (= 0 (bitwise-and byte-address (- bytes-per-cell 1)))) (assertion-violation 'word-ref "unaligned address error" address) (do ((byte-offset 0 (+ byte-offset 1)) (shift-offset (- bits-per-cell bits-per-byte) (- shift-offset bits-per-byte)) (word 0 (+ word (arithmetic-shift ((if (= 0 byte-offset) signed-code-vector-ref code-vector-ref) vector (+ byte-address byte-offset)) shift-offset)))) ((or (>= byte-offset bytes-per-cell) (< shift-offset 0)) word)))))) (define (unsigned-byte-set! address value) (let ((address (address-index address))) (code-vector-set! (address->vector address) (address->vector-index address) (bitwise-and 255 value)))) (define (word-set! address value) (let ((address (address-index address))) (let ((vector (address->vector address)) (byte-address (address->vector-index address))) (if (not (= 0 (bitwise-and byte-address 3))) (assertion-violation 'word-set! "unaligned address error" address)) (do ((byte-offset 0 (+ byte-offset 1)) (shift-offset (- bits-per-cell bits-per-byte) (- shift-offset bits-per-byte))) ((or (>= byte-offset bytes-per-cell) (< shift-offset 0))) (code-vector-set! vector (+ byte-address byte-offset) (bitwise-and 255 (arithmetic-shift value (- shift-offset)))))))) ;; With the right access to the flonum bits we could actually make these ;; work. Something to do later. (define (flonum-ref address) (if #t ; work around type checker bug (assertion-violation 'flonum-ref "call to FLONUM-REF" address))) (define (flonum-set! address value) (if #t ; work around type checker bug (assertion-violation 'flonum-set! "call to FLONUM-SET!" address value))) ;; Block I/O procedures. (define (write-block port address count) (let ((address (address-index address))) (let ((vector (address->vector address)) (byte-address (address->vector-index address))) (do ((i 0 (+ i 1))) ((>= i count)) (write-byte (code-vector-ref vector (+ i byte-address)) port)) (enum errors no-errors)))) (define (read-block port address count) (let ((address (address-index address))) (cond ((not (byte-ready? port)) (values 0 #f (enum errors no-errors))) ((eof-object? (peek-byte port)) (values 0 #t (enum errors no-errors))) (else (let ((vector (address->vector address)) (byte-address (address->vector-index address))) (let loop ((i 0)) (if (or (= i count) (not (byte-ready? port))) (values i #f (enum errors no-errors)) (let ((b (read-byte port))) (cond ((eof-object? b) (values i #f (enum errors no-errors))) (else (code-vector-set! vector (+ i byte-address) b) (loop (+ i 1)))))))))))) (define (copy-memory! from to count) (let ((from (address-index from)) (to (address-index to))) (let ((from-vector (address->vector from)) (from-address (address->vector-index from)) (to-vector (address->vector to)) (to-address (address->vector-index to))) (if (>= from-address to-address) (do ((i 0 (+ i 1))) ((>= i count)) (code-vector-set! to-vector (+ i to-address) (code-vector-ref from-vector (+ i from-address)))) (do ((i (- count 1) (- i 1))) ((negative? i)) (code-vector-set! to-vector (+ i to-address) (code-vector-ref from-vector (+ i from-address)))))))) (define (memory-equal? from to count) (let ((from (address-index from)) (to (address-index to))) (let ((from-vector (address->vector from)) (from-address (address->vector-index from)) (to-vector (address->vector to)) (to-address (address->vector-index to))) (let loop ((i 0)) (cond ((>= i count) #t) ((= (code-vector-ref to-vector (+ i to-address)) (code-vector-ref from-vector (+ i from-address))) (loop (+ i 1))) (else #f)))))) ;; Turn the LENGTH bytes starting from ADDRESS into a string. (define (char-pointer->string address length) (let ((address (address-index address))) (let ((vector (address->vector address)) (byte-address (address->vector-index address)) (string (make-string length))) (do ((i 0 (+ i 1))) ((= i length)) (string-set! string i (ascii->char (code-vector-ref vector (+ byte-address i))))) string))) ;; Turn the bytes from ADDRESS to the next nul (byte equal to 0) into a ;; string. This is a trivial operation in C. (define (char-pointer->nul-terminated-string address) (let ((index (address-index address))) (let ((vector (address->vector index)) (byte-address (address->vector-index index))) (char-pointer->string address (index-of-first-nul vector byte-address))))) (define (index-of-first-nul vector address) (let loop ((i address)) (cond ((= i (code-vector-length vector)) (assertion-violation 'char-pointer->string "CHAR-POINTER->STRING called on pointer with no nul termination")) ((= 0 (code-vector-ref vector i)) (- i address)) (else (loop (+ i 1))))))