;;;; support for threads in the target machine ;;;; This software is part of the SBCL system. See the README file for ;;;; more information. ;;;; ;;;; This software is derived from the CMU CL system, which was ;;;; written at Carnegie Mellon University and released into the ;;;; public domain. The software is in the public domain and is ;;;; provided with absolutely no warranty. See the COPYING and CREDITS ;;;; files for more information. (in-package "SB!THREAD") ;;; CAS Lock ;;; ;;; Locks don't come any simpler -- or more lightweight than this. While ;;; this is probably a premature optimization for most users, we still ;;; need it internally for implementing condition variables outside Futex ;;; builds. (defmacro with-cas-lock ((place) &body body) #!+sb-doc "Runs BODY with interrupts disabled and *CURRENT-THREAD* compare-and-swapped into PLACE instead of NIL. PLACE must be a place acceptable to COMPARE-AND-SWAP, and must initially hold NIL. WITH-CAS-LOCK is suitable mostly when the critical section needing protection is very small, and cost of allocating a separate lock object would be prohibitive. While it is the most lightweight locking constructed offered by SBCL, it is also the least scalable if the section is heavily contested or long. WITH-CAS-LOCK can be entered recursively." `(without-interrupts (%with-cas-lock (,place) ,@body))) (defmacro %with-cas-lock ((place) &body body &environment env) (with-unique-names (owner self) (multiple-value-bind (vars vals old new cas-form read-form) (sb!ext:get-cas-expansion place env) `(let* (,@(mapcar #'list vars vals) (,owner (progn (barrier (:read)) ,read-form)) (,self *current-thread*) (,old nil) (,new ,self)) (unwind-protect (progn (unless (eq ,owner ,self) (loop until (loop repeat 100 when (and (progn (barrier (:read)) (not ,read-form)) (not (setf ,owner ,cas-form))) return t else do (sb!ext:spin-loop-hint)) do (thread-yield))) ,@body) (unless (eq ,owner ,self) (let ((,old ,self) (,new nil)) (unless (eq ,old ,cas-form) (bug "Failed to release CAS lock!"))))))))) ;;; Conditions (define-condition thread-error (error) ((thread :reader thread-error-thread :initarg :thread)) #!+sb-doc (:documentation "Conditions of type THREAD-ERROR are signalled when thread operations fail. The offending thread is initialized by the :THREAD initialization argument and read by the function THREAD-ERROR-THREAD.")) (define-condition simple-thread-error (thread-error simple-condition) ()) (define-condition thread-deadlock (thread-error) ((cycle :initarg :cycle :reader thread-deadlock-cycle)) (:report (lambda (condition stream) (let* ((*print-circle* t) (cycle (thread-deadlock-cycle condition)) (start (caar cycle))) (format stream "Deadlock cycle detected:~%") (loop for part = (pop cycle) while part do (format stream " ~S~% waited for:~% ~S~% owned by:~%" (car part) (cdr part))) (format stream " ~S~%" start))))) #!+sb-doc (setf (fdocumentation 'thread-error-thread 'function) "Return the offending thread that the THREAD-ERROR pertains to.") (define-condition symbol-value-in-thread-error (cell-error thread-error) ((info :reader symbol-value-in-thread-error-info :initarg :info)) (:report (lambda (condition stream) (destructuring-bind (op problem) (symbol-value-in-thread-error-info condition) (format stream "Cannot ~(~A~) value of ~S in ~S: ~S" op (cell-error-name condition) (thread-error-thread condition) (ecase problem (:unbound-in-thread "the symbol is unbound in thread.") (:no-tls-value "the symbol has no thread-local value.") (:thread-dead "the thread has exited.") (:invalid-tls-value "the thread-local value is not valid.")))))) #!+sb-doc (:documentation "Signalled when SYMBOL-VALUE-IN-THREAD or its SETF version fails due to eg. the symbol not having a thread-local value, or the target thread having exited. The offending symbol can be accessed using CELL-ERROR-NAME, and the offending thread using THREAD-ERROR-THREAD.")) (define-condition join-thread-error (thread-error) ((problem :initarg :problem :reader join-thread-problem)) (:report (lambda (c s) (ecase (join-thread-problem c) (:abort (format s "Joining thread failed: thread ~A ~ did not return normally." (thread-error-thread c))) (:timeout (format s "Joining thread timed out: thread ~A ~ did not exit in time." (thread-error-thread c)))))) #!+sb-doc (:documentation "Signalled when joining a thread fails due to abnormal exit of the thread to be joined. The offending thread can be accessed using THREAD-ERROR-THREAD.")) (define-deprecated-function :late "1.0.29.17" join-thread-error-thread thread-error-thread (condition) (thread-error-thread condition)) (define-condition interrupt-thread-error (thread-error) () (:report (lambda (c s) (format s "Interrupt thread failed: thread ~A has exited." (thread-error-thread c)))) #!+sb-doc (:documentation "Signalled when interrupting a thread fails because the thread has already exited. The offending thread can be accessed using THREAD-ERROR-THREAD.")) (define-deprecated-function :late "1.0.29.17" interrupt-thread-error-thread thread-error-thread (condition) (thread-error-thread condition)) ;;; Of the WITH-PINNED-OBJECTS in this file, not every single one is ;;; necessary because threads are only supported with the conservative ;;; gencgc and numbers on the stack (returned by GET-LISP-OBJ-ADDRESS) ;;; are treated as references. ;;; set the doc here because in early-thread FDOCUMENTATION is not ;;; available, yet #!+sb-doc (setf (fdocumentation '*current-thread* 'variable) "Bound in each thread to the thread itself.") #!+sb-doc (setf (fdocumentation 'thread-name 'function) "Name of the thread. Can be assigned to using SETF. Thread names can be arbitrary printable objects, and need not be unique.") (def!method print-object ((thread thread) stream) (print-unreadable-object (thread stream :type t :identity t) (let* ((cookie (list thread)) (info (if (thread-alive-p thread) :running (multiple-value-list (join-thread thread :default cookie)))) (state (if (eq :running info) (let* ((thing (progn (barrier (:read)) (thread-waiting-for thread)))) (typecase thing (cons (list "waiting on:" (cdr thing) "timeout: " (car thing))) (null (list info)) (t (list "waiting on:" thing)))) (if (eq cookie (car info)) (list :aborted) :finished))) (values (when (eq :finished state) info)) (*print-level* 4)) (format stream "~@[~S ~]~:[~{~I~A~^~2I~_ ~}~_~;~A~:[ no values~; values: ~:*~{~S~^, ~}~]~]" (thread-name thread) (eq :finished state) state values)))) (defun print-lock (lock name owner stream) (let ((*print-circle* t)) (print-unreadable-object (lock stream :type t :identity (not name)) (if owner (format stream "~@[~S ~]~2I~_owner: ~S" name owner) (format stream "~@[~S ~](free)" name))))) (def!method print-object ((mutex mutex) stream) (print-lock mutex (mutex-name mutex) (mutex-owner mutex) stream)) (defun thread-alive-p (thread) #!+sb-doc "Return T if THREAD is still alive. Note that the return value is potentially stale even before the function returns, as the thread may exit at any time." (thread-%alive-p thread)) (defun thread-ephemeral-p (thread) #!+sb-doc "Return T if THREAD is `ephemeral', which indicates that this thread is used by SBCL for internal purposes, and specifically that it knows how to to terminate this thread cleanly prior to core file saving without signalling an error in that case." (thread-%ephemeral-p thread)) ;; A thread is eligible for gc iff it has finished and there are no ;; more references to it. This list is supposed to keep a reference to ;; all running threads. (defvar *all-threads* ()) (defvar *all-threads-lock* (make-mutex :name "all threads lock")) (defvar *default-alloc-signal* nil) (defmacro with-all-threads-lock (&body body) `(with-system-mutex (*all-threads-lock*) ,@body)) (defun list-all-threads () #!+sb-doc "Return a list of the live threads. Note that the return value is potentially stale even before the function returns, as new threads may be created and old ones may exit at any time." (with-all-threads-lock (copy-list *all-threads*))) (declaim (inline current-thread-sap)) (defun current-thread-sap () (sb!vm::current-thread-offset-sap sb!vm::thread-this-slot)) (declaim (inline current-thread-os-thread)) (defun current-thread-os-thread () #!+sb-thread (sap-int (sb!vm::current-thread-offset-sap sb!vm::thread-os-thread-slot)) #!-sb-thread 0) (defvar *initial-thread* nil) (defvar *make-thread-lock*) (defun init-initial-thread () (/show0 "Entering INIT-INITIAL-THREAD") (setf sb!impl::*exit-lock* (make-mutex :name "Exit Lock") *make-thread-lock* (make-mutex :name "Make-Thread Lock")) (let ((initial-thread (%make-thread :name "main thread" :%alive-p t :os-thread (current-thread-os-thread)))) (setq *initial-thread* initial-thread *current-thread* initial-thread) (grab-mutex (thread-result-lock *initial-thread*)) ;; Either *all-threads* is empty or it contains exactly one thread ;; in case we are in reinit since saving core with multiple ;; threads doesn't work. (setq *all-threads* (list initial-thread)))) (defun main-thread () "Returns the main thread of the process." *initial-thread*) (defun main-thread-p (&optional (thread *current-thread*)) "True if THREAD, defaulting to current thread, is the main thread of the process." (eq thread *initial-thread*)) (defmacro return-from-thread (values-form &key allow-exit) "Unwinds from and terminates the current thread, with values from VALUES-FORM as the results visible to JOIN-THREAD. If current thread is the main thread of the process (see MAIN-THREAD-P), signals an error unless ALLOW-EXIT is true, as terminating the main thread would terminate the entire process. If ALLOW-EXIT is true, returning from the main thread is equivalent to calling SB-EXT:EXIT with :CODE 0 and :ABORT NIL. See also: ABORT-THREAD and SB-EXT:EXIT." `(%return-from-thread (multiple-value-list ,values-form) ,allow-exit)) (defun %return-from-thread (values allow-exit) (let ((self *current-thread*)) (cond ((main-thread-p self) (unless allow-exit (error 'simple-thread-error :format-control "~@" :format-arguments (list values) :thread self)) (sb!ext:exit :code 0)) (t (throw '%return-from-thread (values-list values)))))) (defun abort-thread (&key allow-exit) "Unwinds from and terminates the current thread abnormally, causing JOIN-THREAD on current thread to signal an error unless a default-value is provided. If current thread is the main thread of the process (see MAIN-THREAD-P), signals an error unless ALLOW-EXIT is true, as terminating the main thread would terminate the entire process. If ALLOW-EXIT is true, aborting the main thread is equivalent to calling SB-EXT:EXIT code 1 and :ABORT NIL. Invoking the initial ABORT restart estabilished by MAKE-THREAD is equivalent to calling ABORT-THREAD in other than main threads. However, whereas ABORT restart may be rebound, ABORT-THREAD always unwinds the entire thread. (Behaviour of the initial ABORT restart for main thread depends on the :TOPLEVEL argument to SB-EXT:SAVE-LISP-AND-DIE.) See also: RETURN-FROM-THREAD and SB-EXT:EXIT." (let ((self *current-thread*)) (cond ((main-thread-p self) (unless allow-exit (error 'simple-thread-error :format-control "~@")) (sb!ext:exit :code 1)) (t ;; We /could/ use TOPLEVEL-CATCHER or %END-OF-THE-WORLD as well, but ;; this seems tidier. Those to are a bit too overloaded already. (throw '%abort-thread t))))) ;;;; Aliens, low level stuff (define-alien-routine "kill_safely" integer (os-thread #!-alpha unsigned #!+alpha unsigned-int) (signal int)) (define-alien-routine "wake_thread" integer (os-thread unsigned)) #!+sb-thread (progn ;; FIXME it would be good to define what a thread id is or isn't ;; (our current assumption is that it's a fixnum). It so happens ;; that on Linux it's a pid, but it might not be on posix thread ;; implementations. (define-alien-routine ("create_thread" %create-thread) unsigned (lisp-fun-address unsigned)) (declaim (inline %block-deferrable-signals)) (define-alien-routine ("block_deferrable_signals" %block-deferrable-signals) void (where unsigned) (old unsigned)) (defun block-deferrable-signals () (%block-deferrable-signals 0 0)) #!+sb-futex (progn (declaim (inline futex-wait %futex-wait futex-wake)) (define-alien-routine ("futex_wait" %futex-wait) int (word unsigned) (old-value unsigned) (to-sec long) (to-usec unsigned-long)) (defun futex-wait (word old to-sec to-usec) (with-interrupts (%futex-wait word old to-sec to-usec))) (define-alien-routine "futex_wake" int (word unsigned) (n unsigned-long)))) ;;; used by debug-int.lisp to access interrupt contexts #!-(or sb-fluid sb-thread) (declaim (inline sb!vm::current-thread-offset-sap)) #!-sb-thread (defun sb!vm::current-thread-offset-sap (n) (declare (type (unsigned-byte 27) n)) (sap-ref-sap (alien-sap (extern-alien "all_threads" (* t))) (* n sb!vm:n-word-bytes))) #!+sb-thread (defun sb!vm::current-thread-offset-sap (n) (declare (type (unsigned-byte 27) n)) (sb!vm::current-thread-offset-sap n)) (defmacro with-deadlocks ((thread lock &optional (timeout nil timeoutp)) &body forms) (with-unique-names (n-thread n-lock new n-timeout) `(let* ((,n-thread ,thread) (,n-lock ,lock) (,n-timeout ,(when timeoutp `(or ,timeout (when sb!impl::*deadline* sb!impl::*deadline-seconds*)))) (,new (if ,n-timeout ;; Using CONS tells the rest of the system there's a ;; timeout in place, so it isn't considered a deadlock. (cons ,n-timeout ,n-lock) ,n-lock))) (declare (dynamic-extent ,new)) ;; No WITHOUT-INTERRUPTS, since WITH-DEADLOCKS is used ;; in places where interrupts should already be disabled. (unwind-protect (progn (setf (thread-waiting-for ,n-thread) ,new) (barrier (:write)) ,@forms) ;; Interrupt handlers and GC save and restore any ;; previous wait marks using WITHOUT-DEADLOCKS below. (setf (thread-waiting-for ,n-thread) nil) (barrier (:write)))))) ;;;; Mutexes #!+sb-doc (setf (fdocumentation 'make-mutex 'function) "Create a mutex." (fdocumentation 'mutex-name 'function) "The name of the mutex. Setfable.") #!+(and sb-thread sb-futex) (progn (define-structure-slot-addressor mutex-state-address :structure mutex :slot state) ;; Important: current code assumes these are fixnums or other ;; lisp objects that don't need pinning. (defconstant +lock-free+ 0) (defconstant +lock-taken+ 1) (defconstant +lock-contested+ 2)) (defun mutex-owner (mutex) "Current owner of the mutex, NIL if the mutex is free. Naturally, this is racy by design (another thread may acquire the mutex after this function returns), it is intended for informative purposes. For testing whether the current thread is holding a mutex see HOLDING-MUTEX-P." ;; Make sure to get the current value. (sb!ext:compare-and-swap (mutex-%owner mutex) nil nil)) (sb!ext:defglobal **deadlock-lock** nil) ;;; Signals an error if owner of LOCK is waiting on a lock whose release ;;; depends on the current thread. Does not detect deadlocks from sempahores. (defun check-deadlock () (let* ((self *current-thread*) (origin (progn (barrier (:read)) (thread-waiting-for self)))) (labels ((detect-deadlock (lock) (let ((other-thread (mutex-%owner lock))) (cond ((not other-thread)) ((eq self other-thread) (let ((chain (with-cas-lock ((symbol-value '**deadlock-lock**)) (prog1 (deadlock-chain self origin) ;; We're now committed to signaling the ;; error and breaking the deadlock, so ;; mark us as no longer waiting on the ;; lock. This ensures that a single ;; deadlock is reported in only one ;; thread, and that we don't look like ;; we're waiting on the lock when print ;; stuff -- because that may lead to ;; further deadlock checking, in turn ;; possibly leading to a bogus vicious ;; metacycle on PRINT-OBJECT. (setf (thread-waiting-for self) nil))))) (error 'thread-deadlock :thread *current-thread* :cycle chain))) (t (let ((other-lock (progn (barrier (:read)) (thread-waiting-for other-thread)))) ;; If the thread is waiting with a timeout OTHER-LOCK ;; is a cons, and we don't consider it a deadlock -- since ;; it will time out on its own sooner or later. (when (mutex-p other-lock) (detect-deadlock other-lock))))))) (deadlock-chain (thread lock) (let* ((other-thread (mutex-owner lock)) (other-lock (when other-thread (barrier (:read)) (thread-waiting-for other-thread)))) (cond ((not other-thread) ;; The deadlock is gone -- maybe someone unwound ;; from the same deadlock already? (return-from check-deadlock nil)) ((consp other-lock) ;; There's a timeout -- no deadlock. (return-from check-deadlock nil)) ((waitqueue-p other-lock) ;; Not a lock. (return-from check-deadlock nil)) ((eq self other-thread) ;; Done (list (list thread lock))) (t (if other-lock (cons (cons thread lock) (deadlock-chain other-thread other-lock)) ;; Again, the deadlock is gone? (return-from check-deadlock nil))))))) ;; Timeout means there is no deadlock (when (mutex-p origin) (detect-deadlock origin) t)))) (defun %try-mutex (mutex new-owner) (declare (type mutex mutex) (optimize (speed 3))) (barrier (:read)) (let ((old (mutex-%owner mutex))) (when (eq new-owner old) (error "Recursive lock attempt ~S." mutex)) #!-sb-thread (when old (error "Strange deadlock on ~S in an unithreaded build?" mutex)) #!-(and sb-thread sb-futex) (and (not old) ;; Don't even bother to try to CAS if it looks bad. (not (sb!ext:compare-and-swap (mutex-%owner mutex) nil new-owner))) #!+(and sb-thread sb-futex) ;; From the Mutex 2 algorithm from "Futexes are Tricky" by Ulrich Drepper. (when (eql +lock-free+ (sb!ext:compare-and-swap (mutex-state mutex) +lock-free+ +lock-taken+)) (let ((prev (sb!ext:compare-and-swap (mutex-%owner mutex) nil new-owner))) (when prev (bug "Old owner in free mutex: ~S" prev)) t)))) #!+sb-thread (defun %%wait-for-mutex (mutex new-owner to-sec to-usec stop-sec stop-usec) (declare (type mutex mutex) (optimize (speed 3))) #!-sb-futex (declare (ignore to-sec to-usec)) #!-sb-futex (flet ((cas () (loop repeat 100 when (and (progn (barrier (:read)) (not (mutex-%owner mutex))) (not (sb!ext:compare-and-swap (mutex-%owner mutex) nil new-owner))) do (return-from cas t) else do (sb!ext:spin-loop-hint)) ;; Check for pending interrupts. (with-interrupts nil))) (declare (dynamic-extent #'cas)) (sb!impl::%%wait-for #'cas stop-sec stop-usec)) #!+sb-futex ;; This is a fairly direct translation of the Mutex 2 algorithm from ;; "Futexes are Tricky" by Ulrich Drepper. (flet ((maybe (old) (when (eql +lock-free+ old) (let ((prev (sb!ext:compare-and-swap (mutex-%owner mutex) nil new-owner))) (when prev (bug "Old owner in free mutex: ~S" prev)) (return-from %%wait-for-mutex t))))) (prog ((old (sb!ext:compare-and-swap (mutex-state mutex) +lock-free+ +lock-taken+))) ;; Got it right off the bat? (maybe old) :retry ;; Mark it as contested, and sleep. (Exception: it was just released.) (when (or (eql +lock-contested+ old) (not (eql +lock-free+ (sb!ext:compare-and-swap (mutex-state mutex) +lock-taken+ +lock-contested+)))) (when (eql 1 (with-pinned-objects (mutex) (futex-wait (mutex-state-address mutex) (get-lisp-obj-address +lock-contested+) (or to-sec -1) (or to-usec 0)))) ;; -1 = EWOULDBLOCK, possibly spurious wakeup ;; 0 = normal wakeup ;; 1 = ETIMEDOUT ***DONE*** ;; 2 = EINTR, a spurious wakeup (return-from %%wait-for-mutex nil))) ;; Try to get it, still marking it as contested. (maybe (sb!ext:compare-and-swap (mutex-state mutex) +lock-free+ +lock-contested+)) ;; Update timeout if necessary. (when stop-sec (setf (values to-sec to-usec) (sb!impl::relative-decoded-times stop-sec stop-usec))) ;; Spin. (go :retry)))) #!+sb-thread (defun %wait-for-mutex (mutex self timeout to-sec to-usec stop-sec stop-usec deadlinep) (with-deadlocks (self mutex timeout) (with-interrupts (check-deadlock)) (tagbody :again (return-from %wait-for-mutex (or (%%wait-for-mutex mutex self to-sec to-usec stop-sec stop-usec) (when deadlinep (signal-deadline) ;; FIXME: substract elapsed time from timeout... (setf (values to-sec to-usec stop-sec stop-usec deadlinep) (decode-timeout timeout)) (go :again))))))) (define-deprecated-function :early "1.0.37.33" get-mutex (grab-mutex) (mutex &optional new-owner (waitp t) (timeout nil)) (declare (ignorable waitp timeout)) (let ((new-owner (or new-owner *current-thread*))) (or (%try-mutex mutex new-owner) #!+sb-thread (when waitp (multiple-value-call #'%wait-for-mutex mutex new-owner timeout (decode-timeout timeout)))))) (defun grab-mutex (mutex &key (waitp t) (timeout nil)) #!+sb-doc "Acquire MUTEX for the current thread. If WAITP is true (the default) and the mutex is not immediately available, sleep until it is available. If TIMEOUT is given, it specifies a relative timeout, in seconds, on how long GRAB-MUTEX should try to acquire the lock in the contested case. If GRAB-MUTEX returns T, the lock acquisition was successful. In case of WAITP being NIL, or an expired TIMEOUT, GRAB-MUTEX may also return NIL which denotes that GRAB-MUTEX did -not- acquire the lock. Notes: - GRAB-MUTEX is not interrupt safe. The correct way to call it is: (WITHOUT-INTERRUPTS ... (ALLOW-WITH-INTERRUPTS (GRAB-MUTEX ...)) ...) WITHOUT-INTERRUPTS is necessary to avoid an interrupt unwinding the call while the mutex is in an inconsistent state while ALLOW-WITH-INTERRUPTS allows the call to be interrupted from sleep. - (GRAB-MUTEX :timeout 0.0) differs from (GRAB-MUTEX :waitp nil) in that the former may signal a DEADLINE-TIMEOUT if the global deadline was due already on entering GRAB-MUTEX. The exact interplay of GRAB-MUTEX and deadlines are reserved to change in future versions. - It is recommended that you use WITH-MUTEX instead of calling GRAB-MUTEX directly. " (declare (ignorable waitp timeout)) (let ((self *current-thread*)) (or (%try-mutex mutex self) #!+sb-thread (when waitp (multiple-value-call #'%wait-for-mutex mutex self timeout (decode-timeout timeout)))))) (defun release-mutex (mutex &key (if-not-owner :punt)) #!+sb-doc "Release MUTEX by setting it to NIL. Wake up threads waiting for this mutex. RELEASE-MUTEX is not interrupt safe: interrupts should be disabled around calls to it. If the current thread is not the owner of the mutex then it silently returns without doing anything (if IF-NOT-OWNER is :PUNT), signals a WARNING (if IF-NOT-OWNER is :WARN), or releases the mutex anyway (if IF-NOT-OWNER is :FORCE)." (declare (type mutex mutex)) ;; Order matters: set owner to NIL before releasing state. (let* ((self *current-thread*) (old-owner (sb!ext:compare-and-swap (mutex-%owner mutex) self nil))) (unless (eq self old-owner) (ecase if-not-owner ((:punt) (return-from release-mutex nil)) ((:warn) (warn "Releasing ~S, owned by another thread: ~S" mutex old-owner)) ((:force))) (setf (mutex-%owner mutex) nil) ;; FIXME: Is a :memory barrier too strong here? Can we use a :write ;; barrier instead? (barrier (:memory))) #!+(and sb-thread sb-futex) (when old-owner ;; FIXME: once ATOMIC-INCF supports struct slots with word sized ;; unsigned-byte type this can be used: ;; ;; (let ((old (sb!ext:atomic-incf (mutex-state mutex) -1))) ;; (unless (eql old +lock-free+) ;; (setf (mutex-state mutex) +lock-free+) ;; (with-pinned-objects (mutex) ;; (futex-wake (mutex-state-address mutex) 1)))) (let ((old (sb!ext:compare-and-swap (mutex-state mutex) +lock-taken+ +lock-free+))) (when (eql old +lock-contested+) (sb!ext:compare-and-swap (mutex-state mutex) +lock-contested+ +lock-free+) (with-pinned-objects (mutex) (futex-wake (mutex-state-address mutex) 1)))) nil))) ;;;; Waitqueues/condition variables #!+(or (not sb-thread) sb-futex) (defstruct (waitqueue (:constructor %make-waitqueue)) #!+sb-doc "Waitqueue type." (name nil :type (or null thread-name)) #!+(and sb-thread sb-futex) (token nil)) #!+(and sb-thread (not sb-futex)) (progn (defstruct (waitqueue (:constructor %make-waitqueue)) #!+sb-doc "Waitqueue type." (name nil :type (or null thread-name)) ;; For WITH-CAS-LOCK: because CONDITION-WAIT must be able to call ;; %WAITQUEUE-WAKEUP without re-aquiring the mutex, we need a separate ;; lock. In most cases this should be uncontested thanks to the mutex -- ;; the only case where that might not be true is when CONDITION-WAIT ;; unwinds and %WAITQUEUE-DROP is called. %owner %head %tail) (defun %waitqueue-enqueue (thread queue) (setf (thread-waiting-for thread) queue) (let ((head (waitqueue-%head queue)) (tail (waitqueue-%tail queue)) (new (list thread))) (unless head (setf (waitqueue-%head queue) new)) (when tail (setf (cdr tail) new)) (setf (waitqueue-%tail queue) new) nil)) (defun %waitqueue-drop (thread queue) (setf (thread-waiting-for thread) nil) (let ((head (waitqueue-%head queue))) (do ((list head (cdr list)) (prev nil list)) ((or (null list) (eq (car list) thread)) (when list (let ((rest (cdr list))) (cond (prev (setf (cdr prev) rest)) (t (setf (waitqueue-%head queue) rest prev rest))) (unless rest (setf (waitqueue-%tail queue) prev))))))) nil) (defun %waitqueue-wakeup (queue n) (declare (fixnum n)) (loop while (plusp n) for next = (let ((head (waitqueue-%head queue)) (tail (waitqueue-%tail queue))) (when head (if (eq head tail) (setf (waitqueue-%head queue) nil (waitqueue-%tail queue) nil) (setf (waitqueue-%head queue) (cdr head))) (car head))) while next do (when (eq queue (sb!ext:compare-and-swap (thread-waiting-for next) queue nil)) (decf n))) nil)) (def!method print-object ((waitqueue waitqueue) stream) (print-unreadable-object (waitqueue stream :type t :identity t) (format stream "~@[~A~]" (waitqueue-name waitqueue)))) (defun make-waitqueue (&key name) #!+sb-doc "Create a waitqueue." (%make-waitqueue :name name)) #!+sb-doc (setf (fdocumentation 'waitqueue-name 'function) "The name of the waitqueue. Setfable.") #!+(and sb-thread sb-futex) (define-structure-slot-addressor waitqueue-token-address :structure waitqueue :slot token) (defun condition-wait (queue mutex &key timeout) #!+sb-doc "Atomically release MUTEX and start waiting on QUEUE for till another thread wakes us up using either CONDITION-NOTIFY or CONDITION-BROADCAST on that queue, at which point we re-acquire MUTEX and return T. Spurious wakeups are possible. If TIMEOUT is given, it is the maximum number of seconds to wait, including both waiting for the wakeup and the time to re-acquire MUTEX. Unless both wakeup and re-acquisition do not occur within the given time, returns NIL without re-acquiring the mutex. If CONDITION-WAIT unwinds, it may do so with or without the mutex being held. Important: Since CONDITION-WAIT may return without CONDITION-NOTIFY having occurred the correct way to write code that uses CONDITION-WAIT is to loop around the call, checking the the associated data: (defvar *data* nil) (defvar *queue* (make-waitqueue)) (defvar *lock* (make-mutex)) ;; Consumer (defun pop-data (&optional timeout) (with-mutex (*lock*) (loop until *data* do (or (condition-wait *queue* *lock* :timeout timeout) ;; Lock not held, must unwind without touching *data*. (return-from pop-data nil))) (pop *data*))) ;; Producer (defun push-data (data) (with-mutex (*lock*) (push data *data*) (condition-notify *queue*))) " #!-sb-thread (declare (ignore queue)) (assert mutex) #!-sb-thread (sb!ext:wait-for nil :timeout timeout) ; Yeah... #!+sb-thread (let ((me *current-thread*)) (barrier (:read)) (assert (eq me (mutex-%owner mutex))) (multiple-value-bind (to-sec to-usec stop-sec stop-usec deadlinep) (decode-timeout timeout) (let ((status :interrupted)) ;; Need to disable interrupts so that we don't miss grabbing the ;; mutex on our way out. (without-interrupts (unwind-protect (progn #!-sb-futex (progn (%with-cas-lock ((waitqueue-%owner queue)) (%waitqueue-enqueue me queue)) (release-mutex mutex) (setf status (or (flet ((wakeup () (barrier (:read)) (unless (eq queue (thread-waiting-for me)) :ok))) (declare (dynamic-extent #'wakeup)) (allow-with-interrupts (sb!impl::%%wait-for #'wakeup stop-sec stop-usec))) :timeout))) #!+sb-futex (with-pinned-objects (queue me) (setf (waitqueue-token queue) me) (release-mutex mutex) ;; Now we go to sleep using futex-wait. If anyone else ;; manages to grab MUTEX and call CONDITION-NOTIFY during ;; this comment, it will change the token, and so futex-wait ;; returns immediately instead of sleeping. Ergo, no lost ;; wakeup. We may get spurious wakeups, but that's ok. (setf status (case (allow-with-interrupts (futex-wait (waitqueue-token-address queue) (get-lisp-obj-address me) ;; our way of saying "no ;; timeout": (or to-sec -1) (or to-usec 0))) ((1) ;; 1 = ETIMEDOUT :timeout) (t ;; -1 = EWOULDBLOCK, possibly spurious wakeup ;; 0 = normal wakeup ;; 2 = EINTR, a spurious wakeup :ok))))) #!-sb-futex (%with-cas-lock ((waitqueue-%owner queue)) (if (eq queue (thread-waiting-for me)) (%waitqueue-drop me queue) (unless (eq :ok status) ;; CONDITION-NOTIFY thinks we've been woken up, but really ;; we're unwinding. Wake someone else up. (%waitqueue-wakeup queue 1)))) ;; Update timeout for mutex re-aquisition. (when (and (eq :ok status) to-sec) (setf (values to-sec to-usec) (sb!impl::relative-decoded-times stop-sec stop-usec))) ;; If we ran into deadline, try to get the mutex before ;; signaling. If we don't unwind it will look like a normal ;; return from user perspective. (when (and (eq :timeout status) deadlinep) (let ((got-it (%try-mutex mutex me))) (allow-with-interrupts (signal-deadline) (cond (got-it (return-from condition-wait t)) (t ;; The deadline may have changed. (setf (values to-sec to-usec stop-sec stop-usec deadlinep) (decode-timeout timeout)) (setf status :ok)))))) ;; Re-acquire the mutex for normal return. (when (eq :ok status) (unless (or (%try-mutex mutex me) (allow-with-interrupts (%wait-for-mutex mutex me timeout to-sec to-usec stop-sec stop-usec deadlinep))) (setf status :timeout))))) (or (eq :ok status) (unless (eq :timeout status) ;; The only case we return normally without re-acquiring the ;; mutex is when there is a :TIMEOUT that runs out. (bug "CONDITION-WAIT: invalid status on normal return: ~S" status))))))) (defun condition-notify (queue &optional (n 1)) #!+sb-doc "Notify N threads waiting on QUEUE. IMPORTANT: The same mutex that is used in the corresponding CONDITION-WAIT must be held by this thread during this call." #!-sb-thread (declare (ignore queue n)) #!-sb-thread (error "Not supported in unithread builds.") #!+sb-thread (declare (type (and fixnum (integer 1)) n)) (/show0 "Entering CONDITION-NOTIFY") #!+sb-thread (progn #!-sb-futex (with-cas-lock ((waitqueue-%owner queue)) (%waitqueue-wakeup queue n)) #!+sb-futex (progn ;; No problem if >1 thread notifies during the comment in condition-wait: ;; as long as the value in queue-data isn't the waiting thread's id, it ;; matters not what it is -- using the queue object itself is handy. ;; ;; XXX we should do something to ensure that the result of this setf ;; is visible to all CPUs. ;; ;; ^-- surely futex_wake() involves a memory barrier? (setf (waitqueue-token queue) queue) (with-pinned-objects (queue) (futex-wake (waitqueue-token-address queue) n))))) (defun condition-broadcast (queue) #!+sb-doc "Notify all threads waiting on QUEUE. IMPORTANT: The same mutex that is used in the corresponding CONDITION-WAIT must be held by this thread during this call." (condition-notify queue ;; On a 64-bit platform truncating M-P-F to an int ;; results in -1, which wakes up only one thread. (ldb (byte 29 0) most-positive-fixnum))) ;;;; Semaphores (defstruct (semaphore (:constructor %make-semaphore (name %count))) #!+sb-doc "Semaphore type. The fact that a SEMAPHORE is a STRUCTURE-OBJECT should be considered an implementation detail, and may change in the future." (name nil :type (or null thread-name)) (%count 0 :type (integer 0)) (waitcount 0 :type sb!vm:word) (mutex (make-mutex)) (queue (make-waitqueue))) (setf (fdocumentation 'semaphore-name 'function) "The name of the semaphore INSTANCE. Setfable.") (defstruct (semaphore-notification (:constructor make-semaphore-notification ()) (:copier nil)) #!+sb-doc "Semaphore notification object. Can be passed to WAIT-ON-SEMAPHORE and TRY-SEMAPHORE as the :NOTIFICATION argument. Consequences are undefined if multiple threads are using the same notification object in parallel." (%status nil :type boolean)) (setf (fdocumentation 'make-semaphore-notification 'function) "Constructor for SEMAPHORE-NOTIFICATION objects. SEMAPHORE-NOTIFICATION-STATUS is initially NIL.") (declaim (inline semaphore-notification-status)) (defun semaphore-notification-status (semaphore-notification) #!+sb-doc "Returns T if a WAIT-ON-SEMAPHORE or TRY-SEMAPHORE using SEMAPHORE-NOTIFICATION has succeeded since the notification object was created or cleared." (barrier (:read)) (semaphore-notification-%status semaphore-notification)) (declaim (inline clear-semaphore-notification)) (defun clear-semaphore-notification (semaphore-notification) #!+sb-doc "Resets the SEMAPHORE-NOTIFICATION object for use with another call to WAIT-ON-SEMAPHORE or TRY-SEMAPHORE." (barrier (:write) (setf (semaphore-notification-%status semaphore-notification) nil))) (declaim (inline semaphore-count)) (defun semaphore-count (instance) #!+sb-doc "Returns the current count of the semaphore INSTANCE." (barrier (:read)) (semaphore-%count instance)) (defun make-semaphore (&key name (count 0)) #!+sb-doc "Create a semaphore with the supplied COUNT and NAME." (%make-semaphore name count)) (defun wait-on-semaphore (semaphore &key timeout notification) #!+sb-doc "Decrement the count of SEMAPHORE if the count would not be negative. Else blocks until the semaphore can be decremented. Returns T on success. If TIMEOUT is given, it is the maximum number of seconds to wait. If the count cannot be decremented in that time, returns NIL without decrementing the count. If NOTIFICATION is given, it must be a SEMAPHORE-NOTIFICATION object whose SEMAPHORE-NOTIFICATION-STATUS is NIL. If WAIT-ON-SEMAPHORE succeeds and decrements the count, the status is set to T." (when (and notification (semaphore-notification-status notification)) (with-simple-restart (continue "Clear notification status and continue.") (error "~@" 'wait-on-semaphore semaphore)) (clear-semaphore-notification notification)) ;; A more direct implementation based directly on futexes should be ;; possible. ;; ;; We need to disable interrupts so that we don't forget to ;; decrement the waitcount (which would happen if an asynch ;; interrupt should catch us on our way out from the loop.) ;; ;; FIXME: No timeout on initial mutex acquisition. (with-system-mutex ((semaphore-mutex semaphore) :allow-with-interrupts t) ;; Quick check: is it positive? If not, enter the wait loop. (let ((count (semaphore-%count semaphore))) (cond ((plusp count) (setf (semaphore-%count semaphore) (1- count)) (when notification (setf (semaphore-notification-%status notification) t))) (t (unwind-protect (progn ;; Need to use ATOMIC-INCF despite the lock, because on our ;; way out from here we might not be locked anymore -- so ;; another thread might be tweaking this in parallel using ;; ATOMIC-DECF. No danger over overflow, since there it ;; at most one increment per thread waiting on the semaphore. (sb!ext:atomic-incf (semaphore-waitcount semaphore)) (loop until (plusp (setf count (semaphore-%count semaphore))) do (or (condition-wait (semaphore-queue semaphore) (semaphore-mutex semaphore) :timeout timeout) (return-from wait-on-semaphore nil))) (setf (semaphore-%count semaphore) (1- count)) (when notification (setf (semaphore-notification-%status notification) t))) ;; Need to use ATOMIC-DECF as we may unwind without the lock ;; being held! (sb!ext:atomic-decf (semaphore-waitcount semaphore))))))) t) (defun try-semaphore (semaphore &optional (n 1) notification) #!+sb-doc "Try to decrement the count of SEMAPHORE by N. If the count were to become negative, punt and return NIL, otherwise return true. If NOTIFICATION is given it must be a semaphore notification object with SEMAPHORE-NOTIFICATION-STATUS of NIL. If the count is decremented, the status is set to T." (declare (type (integer 1) n)) (when (and notification (semaphore-notification-status notification)) (with-simple-restart (continue "Clear notification status and continue.") (error "~@" 'try-semaphore semaphore)) (clear-semaphore-notification notification)) (with-system-mutex ((semaphore-mutex semaphore) :allow-with-interrupts t) (let ((new-count (- (semaphore-%count semaphore) n))) (when (not (minusp new-count)) (setf (semaphore-%count semaphore) new-count) (when notification (setf (semaphore-notification-%status notification) t)) ;; FIXME: We don't actually document this -- should we just ;; return T, or document new count as the return? new-count)))) (defun signal-semaphore (semaphore &optional (n 1)) #!+sb-doc "Increment the count of SEMAPHORE by N. If there are threads waiting on this semaphore, then N of them is woken up." (declare (type (integer 1) n)) ;; Need to disable interrupts so that we don't lose a wakeup after ;; we have incremented the count. (with-system-mutex ((semaphore-mutex semaphore) :allow-with-interrupts t) (let ((waitcount (semaphore-waitcount semaphore)) (count (incf (semaphore-%count semaphore) n))) (when (plusp waitcount) (condition-notify (semaphore-queue semaphore) (min waitcount count)))))) ;;;; Job control, independent listeners (defstruct session (lock (make-mutex :name "session lock")) (threads nil) (interactive-threads nil) (interactive-threads-queue (make-waitqueue))) (defvar *session* nil) ;;; The debugger itself tries to acquire the session lock, don't let ;;; funny situations (like getting a sigint while holding the session ;;; lock) occur. At the same time we need to allow interrupts while ;;; *waiting* for the session lock for things like GET-FOREGROUND to ;;; be interruptible. ;;; ;;; Take care: we sometimes need to obtain the session lock while ;;; holding on to *ALL-THREADS-LOCK*, so we must _never_ obtain it ;;; _after_ getting a session lock! (Deadlock risk.) ;;; ;;; FIXME: It would be good to have ordered locks to ensure invariants ;;; like the above. (defmacro with-session-lock ((session) &body body) `(with-system-mutex ((session-lock ,session) :allow-with-interrupts t) ,@body)) (defun new-session () (make-session :threads (list *current-thread*) :interactive-threads (list *current-thread*))) (defun init-job-control () (/show0 "Entering INIT-JOB-CONTROL") (setf *session* (new-session)) (/show0 "Exiting INIT-JOB-CONTROL")) (defun %delete-thread-from-session (thread session) (with-session-lock (session) (setf (session-threads session) (delete thread (session-threads session)) (session-interactive-threads session) (delete thread (session-interactive-threads session))))) (defun call-with-new-session (fn) (%delete-thread-from-session *current-thread* *session*) (let ((*session* (new-session))) (funcall fn))) (defmacro with-new-session (args &body forms) (declare (ignore args)) ;for extensibility (sb!int:with-unique-names (fb-name) `(labels ((,fb-name () ,@forms)) (call-with-new-session (function ,fb-name))))) ;;; Remove thread from its session, if it has one. #!+sb-thread (defun handle-thread-exit (thread) (/show0 "HANDLING THREAD EXIT") (when *exit-in-process* (%exit)) ;; Lisp-side cleanup (with-all-threads-lock (setf (thread-%alive-p thread) nil) (setf (thread-os-thread thread) nil) (setq *all-threads* (delete thread *all-threads*)) (when *session* (%delete-thread-from-session thread *session*)))) (defun %exit-other-threads () ;; Grabbing this lock prevents new threads from ;; being spawned, and guarantees that *ALL-THREADS* ;; is up to date. (with-deadline (:seconds nil :override t) (grab-mutex *make-thread-lock*) (let ((timeout sb!ext:*exit-timeout*) (code *exit-in-process*) (current *current-thread*) (joinees nil) (main nil)) (dolist (thread (list-all-threads)) (cond ((eq thread current)) ((main-thread-p thread) (setf main thread)) (t (handler-case (progn (terminate-thread thread) (push thread joinees)) (interrupt-thread-error ()))))) (with-progressive-timeout (time-left :seconds timeout) (dolist (thread joinees) (join-thread thread :default t :timeout (time-left))) ;; Need to defer till others have joined, because when main ;; thread exits, we're gone. Can't use TERMINATE-THREAD -- would ;; get the exit code wrong. (when main (handler-case (interrupt-thread main (lambda () (setf *exit-in-process* (list code)) (throw 'sb!impl::%end-of-the-world t))) (interrupt-thread-error ())) ;; Normally this never finishes, as once the main-thread unwinds we ;; exit with the right code, but if times out before that happens, ;; we will exit after returning -- or rathe racing the main thread ;; to calling OS-EXIT. (join-thread main :default t :timeout (time-left))))))) (defun terminate-session () #!+sb-doc "Kill all threads in session except for this one. Does nothing if current thread is not the foreground thread." ;; FIXME: threads created in other threads may escape termination (let ((to-kill (with-session-lock (*session*) (and (eq *current-thread* (car (session-interactive-threads *session*))) (session-threads *session*))))) ;; do the kill after dropping the mutex; unwind forms in dying ;; threads may want to do session things (dolist (thread to-kill) (unless (eq thread *current-thread*) ;; terminate the thread but don't be surprised if it has ;; exited in the meantime (handler-case (terminate-thread thread) (interrupt-thread-error ())))))) ;;; called from top of invoke-debugger (defun debugger-wait-until-foreground-thread (stream) "Returns T if thread had been running in background, NIL if it was interactive." (declare (ignore stream)) #!-sb-thread nil #!+sb-thread (prog1 (with-session-lock (*session*) (not (member *current-thread* (session-interactive-threads *session*)))) (get-foreground))) (defun get-foreground () #!-sb-thread t #!+sb-thread (let ((was-foreground t)) (loop (/show0 "Looping in GET-FOREGROUND") (with-session-lock (*session*) (let ((int-t (session-interactive-threads *session*))) (when (eq (car int-t) *current-thread*) (unless was-foreground (format *query-io* "Resuming thread ~A~%" *current-thread*)) (return-from get-foreground t)) (setf was-foreground nil) (unless (member *current-thread* int-t) (setf (cdr (last int-t)) (list *current-thread*))) (condition-wait (session-interactive-threads-queue *session*) (session-lock *session*))))))) (defun release-foreground (&optional next) #!+sb-doc "Background this thread. If NEXT is supplied, arrange for it to have the foreground next." #!-sb-thread (declare (ignore next)) #!-sb-thread nil #!+sb-thread (with-session-lock (*session*) (when (rest (session-interactive-threads *session*)) (setf (session-interactive-threads *session*) (delete *current-thread* (session-interactive-threads *session*)))) (when next (setf (session-interactive-threads *session*) (list* next (delete next (session-interactive-threads *session*))))) (condition-broadcast (session-interactive-threads-queue *session*)))) (defun foreground-thread () (car (session-interactive-threads *session*))) (defun make-listener-thread (tty-name) (assert (probe-file tty-name)) (let* ((in (sb!unix:unix-open (namestring tty-name) sb!unix:o_rdwr #o666)) (out (sb!unix:unix-dup in)) (err (sb!unix:unix-dup in))) (labels ((thread-repl () (sb!unix::unix-setsid) (let* ((sb!impl::*stdin* (make-fd-stream in :input t :buffering :line :dual-channel-p t)) (sb!impl::*stdout* (make-fd-stream out :output t :buffering :line :dual-channel-p t)) (sb!impl::*stderr* (make-fd-stream err :output t :buffering :line :dual-channel-p t)) (sb!impl::*tty* (make-fd-stream err :input t :output t :buffering :line :dual-channel-p t)) (sb!impl::*descriptor-handlers* nil)) (with-new-session () (unwind-protect (sb!impl::toplevel-repl nil) (sb!int:flush-standard-output-streams)))))) (make-thread #'thread-repl)))) ;;;; The beef #!+sb-thread (defun initial-thread-function-trampoline (thread setup-sem real-function arguments arg1 arg2 arg3) ;; In time we'll move some of the binding presently done in C here ;; too. ;; ;; KLUDGE: Here we have a magic list of variables that are not ;; thread-safe for one reason or another. As people report problems ;; with the thread safety of certain variables, (e.g. "*print-case* in ;; multiple threads broken", sbcl-devel 2006-07-14), we add a few more ;; bindings here. The Right Thing is probably some variant of ;; Allegro's *cl-default-special-bindings*, as that is at least ;; accessible to users to secure their own libraries. ;; --njf, 2006-07-15 ;; ;; As it is, this lambda must not cons until we are ready to run ;; GC. Be very careful. (let* ((*current-thread* thread) (*restart-clusters* nil) (*handler-clusters* (sb!kernel::initial-handler-clusters)) (*exit-in-process* nil) (sb!impl::*deadline* nil) (sb!impl::*deadline-seconds* nil) (sb!impl::*step-out* nil) ;; internal printer variables (sb!impl::*previous-case* nil) (sb!impl::*previous-readtable-case* nil) (sb!impl::*internal-symbol-output-fun* nil) (sb!impl::*descriptor-handlers* nil)) ; serve-event ;; Binding from C (setf sb!vm:*alloc-signal* *default-alloc-signal*) (setf (thread-os-thread thread) (current-thread-os-thread)) (with-mutex ((thread-result-lock thread)) (with-all-threads-lock (push thread *all-threads*)) (with-session-lock (*session*) (push thread (session-threads *session*))) (setf (thread-%alive-p thread) t) (when setup-sem (signal-semaphore setup-sem)) ;; Using handling-end-of-the-world would be a bit tricky ;; due to other catches and interrupts, so we essentially ;; re-implement it here. Once and only once more. (catch 'sb!impl::toplevel-catcher (catch 'sb!impl::%end-of-the-world (catch '%abort-thread (with-simple-restart (abort "~@" *current-thread*) (without-interrupts (unwind-protect (with-local-interrupts (setf *gc-inhibit* nil) ;for foreign callbacks (sb!unix::unblock-deferrable-signals) (setf (thread-result thread) (prog1 (cons t (multiple-value-list (unwind-protect (catch '%return-from-thread (if (listp arguments) (apply real-function arguments) (funcall real-function arg1 arg2 arg3))) (when *exit-in-process* (sb!impl::call-exit-hooks))))) #!+sb-safepoint (sb!kernel::gc-safepoint)))) ;; We're going down, can't handle interrupts ;; sanely anymore. GC remains enabled. (block-deferrable-signals) ;; We don't want to run interrupts in a dead ;; thread when we leave WITHOUT-INTERRUPTS. ;; This potentially causes important ;; interupts to be lost: SIGINT comes to ;; mind. (setq *interrupt-pending* nil) #!+sb-thruption (setq *thruption-pending* nil) (handle-thread-exit thread))))))))) (values)) (defun make-thread (function &key name arguments ephemeral) #!+sb-doc "Create a new thread of NAME that runs FUNCTION with the argument list designator provided (defaults to no argument). Thread exits when the function returns. The return values of FUNCTION are kept around and can be retrieved by JOIN-THREAD. Invoking the initial ABORT restart established by MAKE-THREAD terminates the thread. See also: RETURN-FROM-THREAD, ABORT-THREAD." #!-sb-thread (declare (ignore function name arguments ephemeral)) #!-sb-thread (error "Not supported in unithread builds.") #!+sb-thread (assert (or (atom arguments) (null (cdr (last arguments)))) (arguments) "Argument passed to ~S, ~S, is an improper list." 'make-thread arguments) #!+sb-thread (let ((thread (%make-thread :name name :%ephemeral-p ephemeral))) (let* ((setup-sem (make-semaphore :name "Thread setup semaphore")) (real-function (coerce function 'function)) (arguments (if (listp arguments) arguments (list arguments))) #!+win32 (fp-modes (dpb 0 sb!vm::float-sticky-bits ;; clear accrued bits (sb!vm:floating-point-modes))) (initial-function (named-lambda initial-thread-function () ;; Win32 doesn't inherit parent thread's FP modes, ;; while it seems to happen everywhere else #!+win32 (setf (sb!vm:floating-point-modes) fp-modes) ;; As it is, this lambda must not cons until we are ;; ready to run GC. Be very careful. (initial-thread-function-trampoline thread setup-sem real-function arguments nil nil nil)))) ;; If the starting thread is stopped for gc before it signals ;; the semaphore then we'd be stuck. (assert (not *gc-inhibit*)) ;; Keep INITIAL-FUNCTION pinned until the child thread is ;; initialized properly. Wrap the whole thing in ;; WITHOUT-INTERRUPTS because we pass INITIAL-FUNCTION to ;; another thread. (with-system-mutex (*make-thread-lock*) (with-pinned-objects (initial-function) (if (zerop (%create-thread (get-lisp-obj-address initial-function))) (setf thread nil) (wait-on-semaphore setup-sem))))) (or thread (error "Could not create a new thread.")))) (defun join-thread (thread &key (default nil defaultp) timeout) #!+sb-doc "Suspend current thread until THREAD exits. Return the result values of the thread function. If the thread does not exit normally within TIMEOUT seconds return DEFAULT if given, or else signal JOIN-THREAD-ERROR. Trying to join the main thread will cause JOIN-THREAD to block until TIMEOUT occurs or the process exits: when main thread exits, the entire process exits. NOTE: Return convention in case of a timeout is experimental and subject to change." (let ((lock (thread-result-lock thread)) (got-it nil) (problem :timeout)) (without-interrupts (unwind-protect (if (setf got-it (allow-with-interrupts ;; Don't use the timeout if the thread is not alive anymore. (grab-mutex lock :timeout (and (thread-alive-p thread) timeout)))) (cond ((car (thread-result thread)) (return-from join-thread (values-list (cdr (thread-result thread))))) (defaultp (return-from join-thread default)) (t (setf problem :abort))) (when defaultp (return-from join-thread default))) (when got-it (release-mutex lock)))) (error 'join-thread-error :thread thread :problem problem))) (defun destroy-thread (thread) #!+sb-doc "Deprecated. Same as TERMINATE-THREAD." (terminate-thread thread)) #!+sb-safepoint (defun enter-foreign-callback (arg1 arg2 arg3) (initial-thread-function-trampoline (make-foreign-thread :name "foreign callback") nil #'sb!alien::enter-alien-callback t arg1 arg2 arg3)) (defmacro with-interruptions-lock ((thread) &body body) `(with-system-mutex ((thread-interruptions-lock ,thread)) ,@body)) ;;; Called from the signal handler. #!-(or sb-thruption win32) (defun run-interruption () (let ((interruption (with-interruptions-lock (*current-thread*) (pop (thread-interruptions *current-thread*))))) ;; If there is more to do, then resignal and let the normal ;; interrupt deferral mechanism take care of the rest. From the ;; OS's point of view the signal we are in the handler for is no ;; longer pending, so the signal will not be lost. (when (thread-interruptions *current-thread*) (kill-safely (thread-os-thread *current-thread*) sb!unix:sigpipe)) (when interruption (funcall interruption)))) #!+sb-thruption (defun run-interruption () (in-interruption () ;the non-thruption code does this in the signal handler (let ((interruption (with-interruptions-lock (*current-thread*) (pop (thread-interruptions *current-thread*))))) (when interruption (funcall interruption) ;; I tried implementing this function as an explicit LOOP, because ;; if we are currently processing the thruption queue, why not do ;; all of them in one go instead of one-by-one? ;; ;; I still think LOOPing would be basically the right thing ;; here. But suppose some interruption unblocked deferrables. ;; Will the next one be happy with that? The answer is "no", at ;; least in the sense that there are tests which check that ;; deferrables are blocked at the beginning of a thruption, and ;; races that make those tests fail. Whether the tests are ;; misguided or not, it seems easier/cleaner to loop implicitly ;; -- and it's also what AK had implemented in the first place. ;; ;; The implicit loop is achieved by returning to C, but having C ;; call back to us immediately. The runtime will reset the sigmask ;; in the mean time. ;; -- DFL (setf *thruption-pending* t))))) (defun interrupt-thread (thread function) #!+sb-doc "Interrupt THREAD and make it run FUNCTION. The interrupt is asynchronous, and can occur anywhere with the exception of sections protected using SB-SYS:WITHOUT-INTERRUPTS. FUNCTION is called with interrupts disabled, under SB-SYS:ALLOW-WITH-INTERRUPTS. Since functions such as GRAB-MUTEX may try to enable interrupts internally, in most cases FUNCTION should either enter SB-SYS:WITH-INTERRUPTS to allow nested interrupts, or SB-SYS:WITHOUT-INTERRUPTS to prevent them completely. When a thread receives multiple interrupts, they are executed in the order they were sent -- first in, first out. This means that a great degree of care is required to use INTERRUPT-THREAD safely and sanely in a production environment. The general recommendation is to limit uses of INTERRUPT-THREAD for interactive debugging, banning it entirely from production environments -- it is simply exceedingly hard to use correctly. With those caveats in mind, what you need to know when using it: * If calling FUNCTION causes a non-local transfer of control (ie. an unwind), all normal cleanup forms will be executed. However, if the interrupt occurs during cleanup forms of an UNWIND-PROTECT, it is just as if that had happened due to a regular GO, THROW, or RETURN-FROM: the interrupted cleanup form and those following it in the same UNWIND-PROTECT do not get executed. SBCL tries to keep its own internals asynch-unwind-safe, but this is frankly an unreasonable expectation for third party libraries, especially given that asynch-unwind-safety does not compose: a function calling only asynch-unwind-safe function isn't automatically asynch-unwind-safe. This means that in order for an asynch unwind to be safe, the entire callstack at the point of interruption needs to be asynch-unwind-safe. * In addition to asynch-unwind-safety you must consider the issue of reentrancy. INTERRUPT-THREAD can cause function that are never normally called recursively to be re-entered during their dynamic contour, which may cause them to misbehave. (Consider binding of special variables, values of global variables, etc.) Take together, these two restrict the \"safe\" things to do using INTERRUPT-THREAD to a fairly minimal set. One useful one -- exclusively for interactive development use is using it to force entry to debugger to inspect the state of a thread: (interrupt-thread thread #'break) Short version: be careful out there." #!+(and (not sb-thread) win32) #!+(and (not sb-thread) win32) (declare (ignore thread)) (with-interrupt-bindings (with-interrupts (funcall function))) #!-(and (not sb-thread) win32) (let ((os-thread (thread-os-thread thread))) (cond ((not os-thread) (error 'interrupt-thread-error :thread thread)) (t (with-interruptions-lock (thread) ;; Append to the end of the interruptions queue. It's ;; O(N), but it does not hurt to slow interruptors down a ;; bit when the queue gets long. (setf (thread-interruptions thread) (append (thread-interruptions thread) (list (lambda () (without-interrupts (allow-with-interrupts (funcall function)))))))) (when (minusp (wake-thread os-thread)) (error 'interrupt-thread-error :thread thread)))))) (defun terminate-thread (thread) #!+sb-doc "Terminate the thread identified by THREAD, by interrupting it and causing it to call SB-EXT:ABORT-THREAD with :ALLOW-EXIT T. The unwind caused by TERMINATE-THREAD is asynchronous, meaning that eg. thread executing (let (foo) (unwind-protect (progn (setf foo (get-foo)) (work-on-foo foo)) (when foo ;; An interrupt occurring inside the cleanup clause ;; will cause cleanups from the current UNWIND-PROTECT ;; to be dropped. (release-foo foo)))) might miss calling RELEASE-FOO despite GET-FOO having returned true if the interrupt occurs inside the cleanup clause, eg. during execution of RELEASE-FOO. Thus, in order to write an asynch unwind safe UNWIND-PROTECT you need to use WITHOUT-INTERRUPTS: (let (foo) (sb-sys:without-interrupts (unwind-protect (progn (setf foo (sb-sys:allow-with-interrupts (get-foo))) (sb-sys:with-local-interrupts (work-on-foo foo))) (when foo (release-foo foo))))) Since most libraries using UNWIND-PROTECT do not do this, you should never assume that unknown code can safely be terminated using TERMINATE-THREAD." (interrupt-thread thread (lambda () (abort-thread :allow-exit t)))) (define-alien-routine "thread_yield" int) #!+sb-doc (setf (fdocumentation 'thread-yield 'function) "Yield the processor to other threads.") ;;; internal use only. If you think you need to use these, either you ;;; are an SBCL developer, are doing something that you should discuss ;;; with an SBCL developer first, or are doing something that you ;;; should probably discuss with a professional psychiatrist first #!+sb-thread (progn (defun %thread-sap (thread) (let ((thread-sap (alien-sap (extern-alien "all_threads" (* t)))) (target (thread-os-thread thread))) (loop (when (sap= thread-sap (int-sap 0)) (return nil)) (let ((os-thread (sap-ref-word thread-sap (* sb!vm:n-word-bytes sb!vm::thread-os-thread-slot)))) (when (= os-thread target) (return thread-sap)) (setf thread-sap (sap-ref-sap thread-sap (* sb!vm:n-word-bytes sb!vm::thread-next-slot))))))) (defun %symbol-value-in-thread (symbol thread) ;; Prevent the thread from dying completely while we look for the TLS ;; area... (with-all-threads-lock (if (thread-alive-p thread) (let* ((offset (sb!kernel:get-lisp-obj-address (sb!vm::symbol-tls-index symbol))) (obj (sap-ref-lispobj (%thread-sap thread) offset)) (tl-val (sb!kernel:get-lisp-obj-address obj))) (cond ((zerop offset) (values nil :no-tls-value)) ((or (eql tl-val sb!vm:no-tls-value-marker-widetag) (eql tl-val sb!vm:unbound-marker-widetag)) (values nil :unbound-in-thread)) (t (values obj :ok)))) (values nil :thread-dead)))) (defun %set-symbol-value-in-thread (symbol thread value) (with-pinned-objects (value) ;; Prevent the thread from dying completely while we look for the TLS ;; area... (with-all-threads-lock (if (thread-alive-p thread) (let ((offset (sb!kernel:get-lisp-obj-address (sb!vm::symbol-tls-index symbol)))) (cond ((zerop offset) (values nil :no-tls-value)) (t (setf (sap-ref-lispobj (%thread-sap thread) offset) value) (values value :ok)))) (values nil :thread-dead))))) (define-alien-variable tls-index-start unsigned-int) ;; Get values from the TLS area of the current thread. (defun %thread-local-references () (without-gcing (let ((sap (%thread-sap *current-thread*))) (loop for index from tls-index-start below (symbol-value 'sb!vm::*free-tls-index*) for value = (sap-ref-word sap (* sb!vm:n-word-bytes index)) for (obj ok) = (multiple-value-list (sb!kernel:make-lisp-obj value nil)) unless (or (not ok) (typep obj '(or fixnum character)) (member value '(#.sb!vm:no-tls-value-marker-widetag #.sb!vm:unbound-marker-widetag)) (member obj seen :test #'eq)) collect obj into seen finally (return seen)))))) (defun symbol-value-in-thread (symbol thread &optional (errorp t)) "Return the local value of SYMBOL in THREAD, and a secondary value of T on success. If the value cannot be retrieved (because the thread has exited or because it has no local binding for NAME) and ERRORP is true signals an error of type SYMBOL-VALUE-IN-THREAD-ERROR; if ERRORP is false returns a primary value of NIL, and a secondary value of NIL. Can also be used with SETF to change the thread-local value of SYMBOL. SYMBOL-VALUE-IN-THREAD is primarily intended as a debugging tool, and not as a mechanism for inter-thread communication." (declare (symbol symbol) (thread thread)) #!+sb-thread (multiple-value-bind (res status) (%symbol-value-in-thread symbol thread) (if (eq :ok status) (values res t) (if errorp (error 'symbol-value-in-thread-error :name symbol :thread thread :info (list :read status)) (values nil nil)))) #!-sb-thread (if (boundp symbol) (values (symbol-value symbol) t) (if errorp (error 'symbol-value-in-thread-error :name symbol :thread thread :info (list :read :unbound-in-thread)) (values nil nil)))) (defun (setf symbol-value-in-thread) (value symbol thread &optional (errorp t)) (declare (symbol symbol) (thread thread)) #!+sb-thread (multiple-value-bind (res status) (%set-symbol-value-in-thread symbol thread value) (if (eq :ok status) (values res t) (if errorp (error 'symbol-value-in-thread-error :name symbol :thread thread :info (list :write status)) (values nil nil)))) #!-sb-thread (if (boundp symbol) (values (setf (symbol-value symbol) value) t) (if errorp (error 'symbol-value-in-thread-error :name symbol :thread thread :info (list :write :unbound-in-thread)) (values nil nil)))) (defun sb!vm::locked-symbol-global-value-add (symbol-name delta) (sb!vm::locked-symbol-global-value-add symbol-name delta)) ;;;; Stepping (defun thread-stepping () (make-lisp-obj (sap-ref-word (current-thread-sap) (* sb!vm::thread-stepping-slot sb!vm:n-word-bytes)))) (defun (setf thread-stepping) (value) (setf (sap-ref-word (current-thread-sap) (* sb!vm::thread-stepping-slot sb!vm:n-word-bytes)) (get-lisp-obj-address value)))