;;; Copyright (c) 1993 by Olin Shivers. ;;; Signal handler system ;;; The principal trickiness here is that we have to interface to Unix signals ;;; *through* an intermediate interface, the S48 vm's idea of interrupts. ;;; So there is a difference between delivering a signal to the underlying ;;; Unix process and delivering it to the program that runs on the VM. ;;; ;;; One effect is that we have two separate codes for the same thing -- the ;;; Unix signal code, and the S48 interrupt value. E.g., SIGNAL/TSTP and ;;; INTERRUPT/TSTP. ;;; These system calls can return EINTR or restart. In order for the S48 vm's ;;; interrupt system to detect a signal and invoke the handler, they *must* ;;; return EINTR, and this must cause a return from C to Scheme. ;;; ;;; open close dup2 accept connect ;;; read recv recvfrom recvmsg ;;; write send sendto sendmsg ;;; select ;;; wait ;;; fcntl* ioctl ;;; sigsuspend ;;; HP-UX, but I don't use: poll lockf msem_lock msgsnd msgrcv semop ;;; ;;; * Only during a F_SETLKW ;;; ;;; From rts/interrupt.scm (package interrupts, interface interrupts-interface) ;;; WITH-INTERRUPTS INTERRUPT-HANDLERS SET-ENABLED-INTERRUPTS ! ;;; ENABLED-INTERRUPTS ;;; Must define WITH-INTERRUPTS* and WITH-INTERRUPTS. ;;; Map a Unix async signal to its S48 interrupt value. ;;; -1 => Not defined. (import-lambda-definition %signal->interrupt (sig) "sig2interrupt") (define (signal->interrupt sig) (let ((int (%signal->interrupt sig))) (if (>= int 0) int (error "Unix signal has no Scheme 48 interrupt." sig)))) (define (interrupt-enabled? int mask) (interrupt-in-set? int mask)) (define (interrupt-enable int mask) (insert-interrupt int mask)) (define *enabled-interrupts* (let lp ((i 0) (mask 0)) (if (= i number-of-interrupts) mask (lp (+ i 1) (interrupt-enable i mask))))) (define (enabled-interrupts) *enabled-interrupts*) (define *pending-interrupts* 0) (define (interrupt-pending? int) (interrupt-in-set? int *pending-interrupts*)) (define (make-interrupt-pending int) (set! *pending-interrupts* (insert-interrupt int *pending-interrupts*))) (define (remove-pending-interrupt int) (set! *pending-interrupts* (remove-interrupt int *pending-interrupts*))) ;;; I'm trying to be consistent about the ! suffix -- I don't use it ;;; when frobbing process state. This is not a great rule; perhaps I ;;; should change it. ;;; ;;; I think you should... (define (set-enabled-interrupts new-enabled-interrupts) (let ((old-enabled-interrupts *enabled-interrupts*)) ;;; set it here so the handlers see the correct value (set! *enabled-interrupts* new-enabled-interrupts) (do ((int 0 (+ int 1))) ((= int number-of-interrupts) new-enabled-interrupts) (let ((old-state (interrupt-enabled? int old-enabled-interrupts)) (new-state (interrupt-enabled? int new-enabled-interrupts))) (if (and (not old-state) new-state (interrupt-pending? int)) (begin (remove-pending-interrupt int) (call-interrupt-handler int))))))) (define-simple-syntax (with-enabled-interrupts interrupt-set body ...) (begin (with-enabled-interrupts* interrupt-set (lambda () body ...)))) (define (with-enabled-interrupts* interrupt-set thunk) (let ((before *enabled-interrupts*)) (set-enabled-interrupts interrupt-set) (let ((return (thunk))) (set-enabled-interrupts before) return))) (define *interrupt-handlers-vector*) (define (install-fresh-interrupt-handlers-vector!) (set! *interrupt-handlers-vector* (make-vector number-of-interrupts #t))) (define (interrupt-handlers-vector) *interrupt-handlers-vector*) (define (interrupt-handler-ref int) (if (or (< int 0) (>= int number-of-interrupts)) (error "ill signum in interrupt-handler-ref" int) (vector-ref *interrupt-handlers-vector* int))) (define (call-interrupt-handler int) (let ((handler (interrupt-handler-ref int))) (case handler ((#t) ((vector-ref default-int-handler-vec int) (enabled-interrupts))) ((#f) (if #f #f)) (else (handler (enabled-interrupts)))))) ;;; Get/Set signal handlers ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;; When you set a signal's handler to "default," if the default for that ;;; signal is something other than "ignore," we actually install this guy. ;;; When he is called by the S48 interrupt system, he'll magically make ;;; the default action happen (by calling C code that *really* sets the ;;; handler to SIGDFL, and then re-sending the signal). This basically ;;; terminates the process, since if the default isn't "ignore," it's always ;;; "terminate" of some kind. Doing it this way means the exit code given ;;; to our waiting parent proc correctly reflects how we died, and also ;;; makes the core dump happen if it should. Details, details. (import-lambda-definition %do-default-sigaction (signal) "do_default_sigaction") (define default-int-handler-vec ;; Non-Unix-signal interrupts just get their default values from ;; the current value of I-H. (let ((v (make-vector 32))) (do ((sig 31 (- sig 1))) ; For each Unix signal ((< sig 0)) ; make & install a default (let ((i (%signal->interrupt sig))) ; signal handler. (if (>= i 0) ; Don't mess with non-signal interrupts. (vector-set! v i (if (memv sig signals-ignored-by-default) (lambda (enabled-interrupts) #f) (lambda (enabled-interrupts) (%do-default-sigaction sig))))))) v)) ;;; HANDLER is #f (ignore), #t (default), or a procedure taking an integer ;;; argument. The interrupt is delivered to a procedure by (1) setting the ;;; ENABLED-INTERRUPTS register to 0 (i.e., blocking all interrupts), and (2) ;;; applying the procedure to the previous value of the ENABLED-INTERRUPTS ;;; register. If the procedure returns normally, the ENABLED-INTERRUPTS ;;; register will be restored to its previous value. (define (set-interrupt-handler int handler) (if (or (< int 0) (>= int number-of-interrupts)) (error "ill signum in set-interrupt-handler!" int) (let ((old-handler (vector-ref *interrupt-handlers-vector* int))) (vector-set! *interrupt-handlers-vector* int handler) old-handler))) (define (interrupt-handler int) (interrupt-handler-ref int)) (define (with-scsh-sighandlers interactive? thunk) (install-fresh-interrupt-handlers-vector!) (do ((sig 32 (- sig 1))) ((< sig 0)) (let ((i (%signal->interrupt sig))) (if (not (or (= i -1) (= sig signal/alrm))) ; Leave alarm handler alone. (set-interrupt-handler i #t)))) (let ((scsh-initial-thread ((structure-ref threads-internal current-thread)))) (if (not (eq? (thread-name scsh-initial-thread) 'scsh-initial-thread)) (error "sighandler did not find scsh-initial-thread, but" scsh-initial-thread)) ;; Note: this will prevent any other system to work, since it pushes ;; a new command level ! (if interactive? (set-interrupt-handler interrupt/keyboard (lambda stuff ((structure-ref threads-internal schedule-event) scsh-initial-thread (enum (structure-ref threads-internal event-type) interrupt) (enum interrupt keyboard)))))) (run-as-long-as deliver-interrupts thunk (structure-ref threads-internal spawn-on-root) 'deliver-interrupts)) (define (deliver-interrupts) (let lp ((last ((structure-ref sigevents most-recent-sigevent)))) (let* ((event ((structure-ref sigevents next-sigevent-set) last full-interrupt-set)) (interrupt ((structure-ref sigevents sigevent-type) event))) (if (interrupt-enabled? interrupt (enabled-interrupts)) (call-interrupt-handler interrupt) (make-interrupt-pending interrupt)) (lp event)))) ;;; Dealing with synchronous signals (import-lambda-definition ignore-signal (sig) "ignore_signal") (import-lambda-definition handle-signal-default (sig) "handle_signal_default") ;;; I am ashamed to say the 33 below is completely bogus. ;;; What we want is a value that is 1 + max interrupt value. (define int->sig-vec (let ((v (make-vector 33 #f))) (do ((sig 32 (- sig 1))) ((< sig 0)) (let ((i (%signal->interrupt sig))) (if (not (= i -1)) (vector-set! v i sig)))) v)) (define (int->signal i) (and (<= 0 i 32) (vector-ref int->sig-vec i)))