; Copyright (c) 1993-1999 by Richard Kelsey and Jonathan Rees. See file COPYING. ; Ports and port handlers ; See doc/io.txt for a description of the i/o system, including ports, ; port handlers, and so forth. ;;; This is not the original file, but an adapted version for scsh ;;; Main difference is, that the ports have a steal-field (define-record-type port-handler :port-handler (really-make-port-handler discloser close buffer-proc ready? steal) port-handler? (discloser port-handler-discloser) (close port-handler-close) (buffer-proc port-handler-buffer-proc) (ready? port-handler-ready?) (steal port-handler-steal)) (define (make-port-handler discloser close buffer-proc ready? . maybe-steal) (if (pair? maybe-steal) (really-make-port-handler discloser close buffer-proc ready? (car maybe-steal)) (really-make-port-handler discloser close buffer-proc ready? (lambda (port-data owner) #f)))) (define (disclose-port port) ((port-handler-discloser (port-handler port)) (port-data port))) (define-method &disclose ((port :input-port)) (disclose-port port)) (define-method &disclose ((port :output-port)) (disclose-port port)) ; The PORT-LOCKED? bit is checked by READ-CHAR, PEEK-CHAR, and WRITE-CHAR ; which are too simple-minded to understand real locks. The three procedures ; below ensure that (PORT-LOCKED? ) is #t whenever someone has aquired ; 's lock. (define (obtain-port-lock port) (set-port-locked?! port #t) (obtain-lock (port-lock port))) (define (maybe-obtain-port-lock port) (let ((ints (set-enabled-interrupts! 0))) (set-port-locked?! port #t) (let ((result (if (maybe-obtain-lock (port-lock port)) #t (begin (set-port-locked?! port #f) #f)))) (set-enabled-interrupts! ints) result))) (define (release-port-lock port) (let ((ints (set-enabled-interrupts! 0))) (if (release-lock (port-lock port)) (set-port-locked?! port #f)) (set-enabled-interrupts! ints))) ; Set up exception handlers for the three unnecessary I/O primitives, ; READ-CHAR, PEEK-CHAR, and WRITE-CHAR. These do the right thing in ; the case of buffer overflow or underflow. ; ; This is abstracted to avoid a circular module dependency. (define (initialize-i/o-handlers! define-exception-handler signal-exception) (define-exception-handler (enum op read-char) (one-arg-proc->handler (read-char-handler #t) signal-exception)) (define-exception-handler (enum op peek-char) (one-arg-proc->handler (read-char-handler #f) signal-exception)) (define-exception-handler (enum op write-char) (two-arg-proc->handler write-char-handler signal-exception))) ; Check the exception and then lock the port. (define (one-arg-proc->handler proc signal-exception) (lambda (opcode reason port) (if (= reason (enum exception buffer-full/empty)) (protect-port-op port (lambda () (proc port))) (signal-exception opcode reason port)))) ; This could combined with on-arg-... if the port were the first argument. (define (two-arg-proc->handler proc signal-exception) (lambda (opcode reason arg port) (if (= reason (enum exception buffer-full/empty)) (protect-port-op port (lambda () (proc arg port))) (signal-exception opcode reason arg port)))) ; If a character is available, use it; if there is an EOF waiting, use that; ; otherwise fill the buffer and go from there. (define (read-char-handler read?) (lambda (port) (cond ((< (port-index port) (port-limit port)) (let ((index (port-index port))) (if read? (set-port-index! port (+ 1 index))) (ascii->char (code-vector-ref (port-buffer port) index)))) ((port-pending-eof? port) (if read? (set-port-pending-eof?! port #f)) (eof-object)) (else (let ((got (fill-port-buffer! port 'any))) (cond ((or (eof-object? got) (= 0 got)) (if (not read?) (set-port-pending-eof?! port #t)) (eof-object)) (else (set-port-index! port (if read? 1 0)) (set-port-limit! port got) (ascii->char (code-vector-ref (port-buffer port) 0))))))))) (define (fill-port-buffer! port needed) ((port-handler-buffer-proc (port-handler port)) (port-data port) (port-buffer port) 0 needed)) ; Write the character if there is room, or call the handler if there is ; no actual buffering. Otherwise use the handler to empty the buffer. (define (write-char-handler char port) (cond ((< (port-index port) (port-limit port)) (code-vector-set! (port-buffer port) (port-index port) (char->ascii char)) (set-port-index! port (+ 1 (port-index port)))) ((= 0 (port-limit port)) ((port-handler-buffer-proc (port-handler port)) (port-data port) char)) (else (empty-port-buffer! port) (code-vector-set! (port-buffer port) 0 (char->ascii char)) (set-port-index! port 1))) (unspecific)) ; This may change PORT's buffer. (define (empty-port-buffer! port) ((port-handler-buffer-proc (port-handler port)) (port-data port) (port-buffer port) 0 (port-index port)) (set-port-index! port 0) (set-port-flushed?! port #t)) (define port-flushed? port-pending-eof?) (define set-port-flushed?! set-port-pending-eof?!) (define (protect-port-op port thunk) (obtain-port-lock port) (let ((result (with-handler (lambda (condition punt) (release-port-lock port) (punt)) thunk))) (release-port-lock port) result)) ;---------------- ; Closing is done with the appropriate handler. ; R4RS says that CLOSE-... is idempotent. (define (close-input-port port) (if (input-port? port) (protect-port-op port (lambda () (if (open-input-port? port) (begin (make-input-port-closed! port) ((port-handler-close (port-handler port)) (port-data port)))))) (call-error "invalid argument" close-input-port port))) (define (close-output-port port) (if (output-port? port) (protect-port-op port (lambda () (if (open-output-port? port) (begin (make-output-port-closed! port) (really-force-output port) ((port-handler-close (port-handler port)) (port-data port)))))) (call-error "invalid argument" close-output-port port))) ;---------------- ; Port operations that do not have opcodes. Each of these needs to check its ; arguments and then lock the port. A macro is used to add the checking and ; locking code. This has to check that the port is a port before locking it ; and then check that it is open after locking it. ; A macro to handle locking ports and checking that they're open. (define-syntax define-port-op (syntax-rules () ((define-port-op (?id ?args ...) ?port ?predicate ?body) (define (?id ?args ...) (if ?predicate ; if args are okay (protect-port-op ?port (lambda () (if (open-port? ?port) ; check that it's open ?body (call-error "invalid argument" ?id ?args ...)))) (call-error "invalid argument" ?id ?args ...)))) ; ?port defaults to the first argument ((define-port-op (?id ?port ?args ...) ?predicate ?body) (define-port-op (?id ?port ?args ...) ?port ?predicate ?body)))) ;---------------- ; See if there is a character available. CHAR-READY? itself is defined ; in current-ports.scm as it needs CURRENT-INPUT-PORT when called with ; no arguments. (define (real-char-ready? port) (if (not (open-input-port? port)) (call-error "invalid argument" char-ready? port) ((port-handler-ready? (port-handler port)) port))) ;---------------- ; Check the arguments and the state of the buffer. Leave any actual work ; up to the next procedure. ; ; The arguments are the same as those for input port handlers: BUFFER is either ; a string or a code vector, START is the initial index, and COUNT is either ; the required number of characters, 'ANY (one or more characters wanted), ; or 'IMMEDIATE (get what's available, but don't block). (define-port-op (read-block buffer start count port) port (and (open-input-port? port) (okay-limits? buffer start (if (or (eq? count 'any) (eq? count 'immediate)) 1 count))) (cond ((port-pending-eof? port) (set-port-pending-eof?! port #f) (eof-object)) ((eq? count 0) 0) (else (really-read-block buffer start count port)))) ; If nothing is available, call the port's handler procedure. Otherwise, ; copy any available characters into the buffer. If more are needed the ; buffer handler is called. (define (really-read-block buffer start count port) (let ((have (- (port-limit port) (port-index port)))) (if (= have 0) ((port-handler-buffer-proc (port-handler port)) (port-data port) buffer start count) (let ((move (min have (if (symbol? count) (- (buffer-length buffer) start) count)))) (copy-bytes! (port-buffer port) (port-index port) buffer start move) (set-port-index! port (+ (port-index port) move)) (if (or (symbol? count) (= move count)) move (read-more buffer start count port move)))))) (define (buffer-length buffer) (if (string? buffer) (string-length buffer) (code-vector-length buffer))) (define (read-more buffer start count port have) (let ((more ((port-handler-buffer-proc (port-handler port)) (port-data port) buffer (+ start have) (- count have)))) (if (eof-object? more) (if (= 0 have) (eof-object) (begin (set-port-pending-eof?! port #t) have)) (+ more have)))) ; Check that BUFFER contains COUNT characters starting from START. (define (okay-limits? buffer start count) (and (integer? start) (exact? start) (<= 0 start) (integer? count) (exact? count) (<= 0 count) (<= (+ start count) (cond ((string? buffer) (string-length buffer)) ((code-vector? buffer) (code-vector-length buffer)) (else -1))))) ;---------------- ; Write the COUNT bytes beginning at START from BUFFER to PORT. (define-port-op (write-block buffer start count port) port (and (open-output-port? port) (okay-limits? buffer start count)) (if (= 0 (port-limit port)) (write-unbuffered-block buffer start count port) (write-buffered-block buffer start count port))) ; WRITE-STRING is a front for WRITE-BLOCK. (define (write-string string port) (write-block string 0 (string-length string) port)) ; CHAR-READY? for output ports. (define (output-port-ready? port) (cond ((not (open-output-port? port)) (call-error "invalid argument" output-port-ready? port)) ((not (maybe-obtain-port-lock port)) #f) ((not (open-port? port)) ; have to check again after the lock call (release-port-lock port) (call-error "invalid argument" output-port-ready? port)) (else (with-handler (lambda (condition punt) (release-port-lock port) (punt)) (lambda () (let ((val ((port-handler-ready? (port-handler port)) port))) (release-port-lock port) val)))))) ; Copy the bytes into the buffer if there is room, otherwise write out anything ; in the buffer and then write BUFFER. (define (write-buffered-block buffer start count port) (let ((space (- (port-limit port) (port-index port)))) (cond ((>= space count) (copy-bytes! buffer start (port-buffer port) (port-index port) count) (set-port-index! port (+ (port-index port) count))) (else (really-force-output port) ((port-handler-buffer-proc (port-handler port)) (port-data port) buffer start count))))) ; For unbuffered ports we have to call the handler on each character ; separately. (define (write-unbuffered-block buffer start count port) (let ((proc (port-handler-buffer-proc (port-handler port))) (data (port-data port)) (string? (string? buffer))) (do ((i 0 (+ i 1))) ((= i count)) (proc data (if string? (string-ref buffer (+ start i)) (ascii->char (code-vector-ref buffer (+ start i)))))))) ;---------------- ; Empty the buffer if it contains anything. (define-port-op (force-output port) (open-output-port? port) (really-force-output port)) (define (really-force-output port) (if (< 0 (port-index port)) (empty-port-buffer! port))) ; Used to avoid race conditions elsewhere. (define (force-output-if-open port) (if (output-port? port) (protect-port-op port (lambda () (if (open-output-port? port) (really-force-output port)))) (call-error "invalid argument" force-output-if-open port))) ;---------------- (define default-buffer-size 4096) ; should get this from the system ;---------------- ; Is PORT open? (define (open-port? port) (not (= 0 (bitwise-and open-port-mask (port-status port))))) (define open-port-mask (bitwise-ior (arithmetic-shift 1 (enum port-status-options open-for-input)) (arithmetic-shift 1 (enum port-status-options open-for-output)))) ;---------------- ; Input ports (define input-port-mask (arithmetic-shift 1 (enum port-status-options input))) (define open-input-port-mask (arithmetic-shift 1 (enum port-status-options open-for-input))) (define open-input-port-status (bitwise-ior input-port-mask open-input-port-mask)) (define (open-input-port? port) (not (= 0 (bitwise-and open-input-port-mask (port-status port))))) (define (make-input-port-closed! port) (set-port-status! port (bitwise-and (port-status port) (bitwise-not open-input-port-mask)))) (define (make-input-port handler data buffer index limit) (if (and (okay-buffer? buffer index limit) (port-handler? handler)) (make-port handler (bitwise-ior input-port-mask open-input-port-mask) (make-lock) #f ; locked? data buffer index limit #f) ; pending-eof? (call-error "invalid argument" make-input-port handler data buffer index limit))) (define (okay-buffer? buffer index limit) (and (code-vector? buffer) (let ((length (code-vector-length buffer))) (integer? limit) (<= 0 limit) (<= limit length) (<= index limit) (integer? index) (<= 0 index) (<= index limit)))) ;---------------- ; Output ports (define output-port-mask (arithmetic-shift 1 (enum port-status-options output))) (define open-output-port-mask (arithmetic-shift 1 (enum port-status-options open-for-output))) (define open-output-port-status (bitwise-ior output-port-mask open-output-port-mask)) (define (open-output-port? port) (not (= 0 (bitwise-and open-output-port-mask (port-status port))))) (define (make-output-port-closed! port) (set-port-status! port (bitwise-and (port-status port) (bitwise-not open-output-port-mask)))) (define (make-output-port handler data buffer index limit) (if (and (okay-buffer? buffer index limit) (> limit 0) (port-handler? handler)) (make-port handler open-output-port-status (make-lock) #f ; locked? data buffer index limit #f) ; pending-eof? (call-error "invalid argument" make-output-port handler data buffer index limit))) (define (make-unbuffered-output-port handler data) (if (port-handler? handler) (make-port handler open-output-port-status (make-lock) #f ; locked? data (make-code-vector 0 0) 0 0 #f) ; pending-eof? (call-error "invalid argument" make-unbuffered-output-port handler data))) (define null-output-port-handler (make-port-handler (lambda (ignore) (list 'null-output-port)) (lambda (ignore) (unspecific)) (lambda (channel buffer start need) (unspecific)) (lambda (port) ; ready? #t) (lambda (ignore1 ignore2) #f))) (define (make-null-output-port) (make-port null-output-port-handler open-output-port-status (make-lock) ; wasted #f ; locked? (unspecific) (make-code-vector 1 0) 0 1 ; if 0 it would look unbuffered #f)) ; pending-eof? ;---------------- ; Code to periodically flush output ports. (define *flush-these-ports* (cons #f '())) (define (initialize-output-port-list!) (set! *flush-these-ports* (cons #f '()))) (define (periodically-force-output! port) (set-cdr! *flush-these-ports* (cons (make-weak-pointer port) (cdr *flush-these-ports*)))) ; Return a list of thunks that will flush the buffer of each open, unlocked ; port that contains characters that have been there since the last time ; this was called. The actual i/o is done using separate threads to keep ; i/o errors from killing anything vital. ; ; If USE-FLUSHED?-FLAGS? is true this won't flush buffers that have been ; flushed by someone else sinse the last call. If it is false then flush ; all non-empty buffers, because the system has nothing to do and is going ; to pause while waiting for external events. (define (output-port-forcers use-flushed?-flags? . maybe-ignore-port-locks?) (let ((ignore-port-locks? (if (null? maybe-ignore-port-locks?) #f #t))) (let loop ((next (cdr *flush-these-ports*)) (last *flush-these-ports*) (thunks '())) (if (null? next) thunks (let ((port (weak-pointer-ref (car next)))) (cond ((or (not port) ; GCed or closed (not (open-output-port? port))) ; so drop it from the list (set-cdr! last (cdr next)) (loop (cdr next) last thunks)) (ignore-port-locks? (cond ((and use-flushed?-flags? ; flushed recently (port-flushed? port)) (set-port-flushed?! port #f) (loop (cdr next) next thunks)) ((< 0 (port-index port)) ; non-empty (loop (cdr next) next (cons (make-forcing-thunk port ignore-port-locks?) thunks))) (else (loop (cdr next) next thunks)))) ((not (maybe-obtain-port-lock port)) ; locked (loop (cdr next) next thunks)) ((and use-flushed?-flags? ; flushed recently (port-flushed? port)) (set-port-flushed?! port #f) (release-port-lock port) (loop (cdr next) next thunks)) ((< 0 (port-index port)) ; non-empty (release-port-lock port) (loop (cdr next) next (cons (make-forcing-thunk port ignore-port-locks?) thunks))) (else ; empty (release-port-lock port) (loop (cdr next) next thunks)))))))) ; Returns a list of the current ports that are flushed whenever. ; This is used to flush channel ports before forking. (define (periodically-flushed-ports) (let ((ints (set-enabled-interrupts! 0))) (let loop ((next (cdr *flush-these-ports*)) (last *flush-these-ports*) (ports '())) (if (null? next) (begin (set-enabled-interrupts! ints) ports) (let ((port (weak-pointer-ref (car next)))) (cond ((or (not port) ; GCed or closed (not (open-output-port? port))) ; so drop it from the list (set-cdr! last (cdr next)) (loop (cdr next) last ports)) (else (loop (cdr next) next (cons port ports))))))))) ; Write out PORT's buffer. If a problem occurs it is reported and PORT ; is closed. (define (make-forcing-thunk port ignore-port-lock?) (lambda () (if (and (report-errors-as-warnings (lambda () (cond ((maybe-obtain-port-lock port) (with-handler (lambda (condition punt) (release-port-lock port) (punt)) (lambda () (really-force-output port) (release-port-lock port)))) (ignore-port-lock? (really-force-output port)))) "error when flushing buffer; closing port" port) (open-output-port? port)) (report-errors-as-warnings (lambda () (make-output-port-closed! port) ((port-handler-close (port-handler port)) (port-data port))) "error when closing port" port)))) ;---------------- ; The following is used to make the REPL's input, output, and error ports ; available after a keyboard interrupt. If PORT is a locked channel port ; we save the its state and then reinitialize it. The OS is told to ; abort any pending operation on the port's channel. Finally, the owning ; thread's continuation is munged to restore the port when the thread ; resumes. Any buffered input is thrown away at that point (it could ; be saved away with the channel). ; ; If the port is locked by us or one of our ancestors there is no point in ; trying to grab it. (define (steal-port! port) (begin (disable-interrupts!) (let ((owner (if (lock-owner-uid (port-lock port)) (thread-uid->thread (lock-owner-uid (port-lock port))) #f))) (if (and owner (not (running? owner))) (begin ; (message (list (thread-uid owner) " " ; (thread-uid (current-thread)) " ")) (really-steal-port! port owner))) (enable-interrupts!)))) (define (really-steal-port! port owner) (let ((lock (port-lock port)) (buffer (port-buffer port)) (index (port-index port)) (limit (port-limit port)) (eof? (port-pending-eof? port)) (status ((port-handler-steal (port-handler port)) (port-data port) owner))) (set-port-buffer! port (make-code-vector (code-vector-length buffer) 0)) (set-port-index! port 0) (set-port-limit! port (if (input-port? port) 0 (code-vector-length buffer))) (set-port-pending-eof?! port #f) (set-port-locked?! port #f) (set-port-lock! port (make-lock)) (interrupt-thread owner (lambda results (obtain-port-lock port) (let ((cleanup (lambda () (set-port-buffer! port buffer) (set-port-index! port index) (set-port-limit! port limit) (set-port-pending-eof?! port eof?) (set-port-lock! port lock)))) (with-handler (lambda (condition punt) (cleanup) (punt)) (lambda () (cond ((output-port? port) (really-force-output port)) ((< (port-index port) (port-limit port)) (warn "dropping input from port" port))) (cleanup) (or status (apply values results))))))) ; if we took OWNER off a channel-wait queue we need to make it ready to run (if status (make-ready owner)))) ;;;;; We don't have unbuffered input ports for now. It's possible to ;;;;; define them if the handler takes care of the char for peek-char, ;;;;; but there is not much point in having them. A buffered port with ;;;;; buffer size 1 provides the same functionality. See 0.54 for ;;;;; unbuffered input ports ;;;;; buffered ports ;;;;; ;;;;; This is only a skeleton. With the switch to 0.54 everything will ;;;;; change anyway, but for char-ready? we need some abstraction now ;;;;; This code is stolen from 0.54's port-buffer.scm and shortened (define (make-buffered-input-port handler data buffer index limit) (if (and (okay-buffer? buffer index limit) (port-handler? handler)) (make-port handler (bitwise-ior input-port-mask open-input-port-mask) (make-lock) #f ; locked? data buffer index limit #f) ; pending-eof? (call-error "invalid argument" make-buffered-input-port handler data buffer index limit))) (define (make-buffered-output-port handler data buffer index limit) (if (and (okay-buffer? buffer index limit) (> limit 0) (port-handler? handler)) (make-port handler open-output-port-status (make-lock) #f ; locked? data buffer index limit #f) ; pending-eof? (call-error "invalid argument" make-buffered-output-port handler data buffer index limit))) (define (okay-buffer? buffer index limit) (and (code-vector? buffer) (let ((length (code-vector-length buffer))) (integer? limit) (integer? index) (exact? limit) (exact? index) (<= 0 limit length) (<= 0 index limit)))) (define (make-buffered-input-port-handler discloser closer! read-block! ready? . maybe-steal!) (apply make-port-handler discloser closer! read-block! (make-char-ready? ready? #t) maybe-steal!)) ;---------------- ; See if there is a character available. (define (make-char-ready? ready? read?) (lambda (port) (cond ((not ((if read? open-input-port? open-output-port?) port)) (call-error "invalid argument" char-ready? port)) ((or (< (port-index port) (port-limit port)) (and read? (port-pending-eof? port))) #t) (else (ready? port))))) (define (make-buffered-output-port-handler discloser closer! buffer-emptier! ready? . maybe-steal!) (apply make-port-handler discloser closer! buffer-emptier! (make-char-ready? ready? #f) maybe-steal!))