(sb!alien:define-alien-routine ("install_handler" install-handler)
sb!alien:unsigned-long
(signal sb!alien:int)
- (handler sb!alien:unsigned-long))
+ (handler sb!alien:unsigned-long)
+ (synchronous boolean))
;;;; interface to enabling and disabling signal handlers
-(defun enable-interrupt (signal handler)
+;;; Note on the SYNCHRONOUS argument: On builds without pseudo-atomic,
+;;; we have no way of knowing whether interrupted code was in an
+;;; allocation sequence, and cannot delay signals until after
+;;; allocation. Any signal that can occur asynchronously must be
+;;; considered unsafe for immediate execution, and the invocation of its
+;;; lisp handler will get delayed into a newly spawned signal handler
+;;; thread. However, there are signals which we must handle
+;;; immediately, because they occur synchonously (hence the boolean flag
+;;; SYNCHRONOUS to this function), luckily implying that the signal
+;;; happens only in specific places (illegal instructions, floating
+;;; point instructions, certain system calls), hopefully ruling out the
+;;; possibility that we would trigger it during allocation.
+
+(defun enable-interrupt (signal handler &key synchronous)
(declare (type (or function fixnum (member :default :ignore)) handler))
(/show0 "enable-interrupt")
(flet ((run-handler (&rest args)
(:ignore sig-ign)
(t
(sb!kernel:get-lisp-obj-address
- #'run-handler))))))
+ #'run-handler)))
+ synchronous)))
(cond ((= result sig-dfl) :default)
((= result sig-ign) :ignore)
(t (the (or function fixnum)
(defun ignore-interrupt (signal)
(enable-interrupt signal :ignore))
\f
+;;;; Support for signal handlers which aren't.
+;;;;
+;;;; On safepoint builds, user-defined Lisp signal handlers do not run
+;;;; in the handler for their signal, because we have no pseudo atomic
+;;;; mechanism to prevent handlers from hitting during allocation.
+;;;; Rather, the signal spawns off a fresh native thread, which calls
+;;;; into lisp with a fake context through this callback:
+
+#!+(and sb-safepoint-strictly (not win32))
+(defun signal-handler-callback (run-handler signal args)
+ (sb!thread::initial-thread-function-trampoline
+ (sb!thread::make-signal-handling-thread :name "signal handler"
+ :signal-number signal)
+ nil (lambda ()
+ (let* ((info (sb!sys:sap-ref-sap args 0))
+ (context (sb!sys:sap-ref-sap args sb!vm:n-word-bytes)))
+ (funcall run-handler signal info context)))
+ nil nil nil nil))
+
+\f
;;;; default LISP signal handlers
;;;;
;;;; Most of these just call ERROR to report the presence of the signal.
(declare (type system-area-pointer context))
(/show "in Lisp-level SIGINT handler" (sap-int context))
(flet ((interrupt-it ()
+ ;; This seems wrong to me on multi-threaded builds. The
+ ;; closed-over signal context belongs to a SIGINT handler.
+ ;; But this function gets run through INTERRUPT-THREAD,
+ ;; i.e. in in a SIGPIPE handler, at a different point in time
+ ;; or even a different thread. How do we know that the
+ ;; SIGINT's context structure from the other thread is still
+ ;; alive and meaningful? Why do we care? If we even need
+ ;; the context and PC, shouldn't they come from the SIGPIPE's
+ ;; context? --DFL
(with-alien ((context (* os-context-t) context))
(with-interrupts
(let ((int (make-condition 'interactive-interrupt
(signal int)
;; Then enter the debugger like BREAK.
(%break 'sigint int))))))
+ #!+sb-safepoint
+ (let ((target (sb!thread::foreground-thread)))
+ ;; Note that INTERRUPT-THREAD on *CURRENT-THREAD* doesn't actually
+ ;; interrupt right away, because deferrables are blocked. Rather,
+ ;; the kernel would arrange for the SIGPIPE to hit when the SIGINT
+ ;; handler is done. However, on safepoint builds, we don't use
+ ;; SIGPIPE and lack an appropriate mechanism to handle pending
+ ;; thruptions upon exit from signal handlers (and this situation is
+ ;; unlike WITHOUT-INTERRUPTS, which handles pending interrupts
+ ;; explicitly at the end). Only as long as safepoint builds pretend
+ ;; to cooperate with signals -- that is, as long as SIGINT-HANDLER
+ ;; is used at all -- detect this situation and work around it.
+ (if (eq target sb!thread:*current-thread*)
+ (interrupt-it)
+ (sb!thread:interrupt-thread target #'interrupt-it)))
+ #!-sb-safepoint
(sb!thread:interrupt-thread (sb!thread::foreground-thread)
#'interrupt-it)))
+#!-sb-wtimer
(defun sigalrm-handler (signal info context)
(declare (ignore signal info context))
(declare (type system-area-pointer context))
(declare (ignore signal code context))
(sb!ext:exit))
+#!-sb-thruption
;;; SIGPIPE is not used in SBCL for its original purpose, instead it's
;;; for signalling a thread that it should look at its interruption
;;; queue. The handler (RUN_INTERRUPTION) just returns if there is
"Enable all the default signals that Lisp knows how to deal with."
(enable-interrupt sigint #'sigint-handler)
(enable-interrupt sigterm #'sigterm-handler)
- (enable-interrupt sigill #'sigill-handler)
+ (enable-interrupt sigill #'sigill-handler :synchronous t)
#!-linux
(enable-interrupt sigemt #'sigemt-handler)
- (enable-interrupt sigfpe #'sb!vm:sigfpe-handler)
- (enable-interrupt sigbus #'sigbus-handler)
+ (enable-interrupt sigfpe #'sb!vm:sigfpe-handler :synchronous t)
+ (enable-interrupt sigbus #'sigbus-handler :synchronous t)
#!-linux
- (enable-interrupt sigsys #'sigsys-handler)
+ (enable-interrupt sigsys #'sigsys-handler :synchronous t)
+ #!-sb-wtimer
(enable-interrupt sigalrm #'sigalrm-handler)
+ #!-sb-thruption
(enable-interrupt sigpipe #'sigpipe-handler)
(enable-interrupt sigchld #'sigchld-handler)
#!+hpux (ignore-interrupt sigxcpu)