709 lines
24 KiB
Scheme
709 lines
24 KiB
Scheme
; Copyright (c) 1993-1999 by Richard Kelsey and Jonathan Rees. See file COPYING.
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; Threads.
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; This is inspired by Haynes et al's engines.
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;
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; The fundamental operation is (RUN <thread> <time>), which runs the thread
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; for the given amount of time.
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;
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; Each thread has:
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; saved continuation
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; saved interrupt mask
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; scheduler, which is the thread that RUNs this one
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; remaining time in clock ticks ('waiting = waiting for events)
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; queue that is holding this thread, if any
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; arguments waiting to be passed to the thread when it is next run
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; dynamic environment
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; dynamic point
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; whatever data the scheduler wants
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; Schedulers also have:
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; list of pending events
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; thread that this scheduler is currently running
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;
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; A `scheduler' is any thread that has called RUN. All threads are organized
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; into a tree by the THREAD-SCHEDULER field, with the pointers pointing from
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; the leaves to the root.
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;
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; There is a doubly linked list of running threads linked by the
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; the thread-scheduler and thread-current-task fields.
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; e1 <-> e2 <-> ... <-> eN-1 <-> eN
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; e1 is the top thread and eN is the thread whose code is actually running.
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; All except eN are in the middle of a call to RUN. The scheduler pointers
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; point to the left and the current-task pointers point to the right.
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;
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; When an thread stops, its scheduler is run and the portion of the list from
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; the stopped thread down is saved for when the stopped thread is resumed. For
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; example, suppose e3 runs out of time. Then the list is shortened to
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; e1 <-> e2 and the e3 <-...-> eN portion is saved. When e3 is resumed,
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; the list is spliced back together and eN's continuation is resumed.
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(define-record-type thread :thread
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(really-make-thread dynamic-env dynamic-point cell-env
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continuation scheduler
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queues arguments
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events current-task uid name)
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thread?
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(dynamic-env thread-dynamic-env) ;Must be first! (See fluid.scm)
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(dynamic-point thread-dynamic-point set-thread-dynamic-point!)
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;Must be second! (See fluid.scm)
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(cell-env thread-cell-env) ;Must be fourth! (See thread-env.scm)
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(continuation thread-continuation set-thread-continuation!)
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(queues thread-queues set-thread-queues!)
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(arguments thread-arguments set-thread-arguments!)
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(time thread-time set-thread-time!)
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(scheduler thread-scheduler set-thread-scheduler!)
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(data thread-data set-thread-data!)
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(events thread-events set-thread-events!) ; schedulers
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(current-task thread-current-task set-thread-current-task!) ; schedulers
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(uid thread-uid) ; for debugging (and as a cheap weak pointer)
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(name thread-name)) ; for debugging
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(define-record-discloser :thread
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(lambda (thread)
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(cons 'thread
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(cons (thread-uid thread)
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(let ((name (thread-name thread)))
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(if name
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(list name)
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'()))))))
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(define *thread-uid* 0)
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(define (make-thread thunk dynamic-env name)
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(let ((thread (really-make-thread dynamic-env
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#f ; dynamic-point root
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(empty-thread-cell-env)
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(thunk->continuation
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(thread-top-level thunk))
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(current-thread) ; scheduler
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#f ; queue
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'() ; arguments
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#f ; events
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#f ; current-task
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*thread-uid*
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name)))
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(set! *thread-uid* (+ *thread-uid* 1))
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thread))
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;----------------
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; Call THUNK and then suspend. The LET is just to give the thunk a name
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; in the debugger. This thunk shows up at the bottom of every ,preview.
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(define (thread-top-level thunk)
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(let ((thread-start (lambda ()
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(call-with-values
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thunk
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(lambda values
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(suspend (enum event-type completed) values))))))
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thread-start))
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; Find the thread with the indicated uid. This is expensive. It is used
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; by rts/channel-port.scm to when forcibly unlocking one of the REPL's ports.
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(define (thread-uid->thread uid)
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(let ((matching-threads (threads-with-uid uid)))
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(cond ((null? matching-threads) #f)
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((null? (cdr matching-threads))
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(car matching-threads))
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(else (set! matching-threads #f)
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((structure-ref primitives collect))
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(let ((new-matching-threads (threads-with-uid uid)))
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(cond ((null? new-matching-threads) #f)
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((null? (cdr new-matching-threads))
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(car new-matching-threads))
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(else (debug-message "duplicate thread uid"
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new-matching-threads)
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(car new-matching-threads))))))))
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(define (threads-with-uid uid)
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(let ((threads (all-threads)))
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(let loop ((i 0))
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(cond ((= i (vector-length threads))
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'())
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((= uid (thread-uid (vector-ref threads i)))
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(cons (vector-ref threads i) (loop (+ i 1))))
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(else
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(loop (+ i 1)))))))
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(define (all-threads)
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((structure-ref primitives find-all-records) :thread))
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; Add EVENT to THREAD's event queue.
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; Called with interrupts disabled.
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(define (add-event! thread event)
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(enqueue! (or (thread-events thread)
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(let ((q (make-queue)))
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(set-thread-events! thread q)
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q))
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event))
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; A bit of magic courtesy of JAR. We need to use PRIMITIVE-CWCC to save
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; thread continuations because CALL-WITH-CURRENT-CONTINUATION saves the
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; dynamic state, including the current thread. PRIMITIVE-CWCC's continuations
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; are not procedures, so we need this thing to convert a thread's initial
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; thunk into a continuation.
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; (Alternatively, we could make a version of CWCC that didn't save the
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; dynamic state. That would slow down context switching, which is
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; presumably more frequent than thread creation.)
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(define (thunk->continuation thunk)
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(compose-continuation thunk #f))
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; Return a continuation that will call PROC with continuation CONT.
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; Synopsis: we grab the current continuation, install the continuation
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; we want to create, and then at the last minute save the new continuation
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; and return it to the one we grabbed on entry.
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(define (compose-continuation proc cont)
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(primitive-cwcc ; grab the current continuation so that
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(lambda (k) ; we can return
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(with-continuation ; install CONT or an empty continuation
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(or cont (loophole :escape #f))
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(lambda ()
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(call-with-values ; install PROC as a continuation
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(lambda ()
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(primitive-cwcc ; grab a continuation that will call PROC and
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(lambda (k2) ; then return to the installed continuation
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(with-continuation ; return the PROC-calling continuation to
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k ; the continuation we grabbed on entry
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(lambda () k2)))))
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proc))))))
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;----------------
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; Enqueueing and dequeuing threads.
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; Rename the queue operations as thread-specific ones (both for clarity
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; and because we will want to use priority queues in the future).
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(define make-thread-queue make-queue)
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(define thread-queue-empty? queue-empty?)
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(define (enqueue-thread! queue thread)
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(if (thread-queues thread)
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(error "enqueued thread being added to another queue" thread queue))
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(set-thread-queues! thread (list queue))
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(enqueue! queue thread))
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(define (multiple-enqueue-thread! queues thread)
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(if (thread-queues thread)
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(error "enqueued thread being added to another queue" thread queues))
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(set-thread-queues! thread queues)
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(for-each (lambda (q) (enqueue! q thread)) queues))
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(define (dequeue-thread! queue)
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(let ((thread (dequeue! queue)))
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(for-each (lambda (q) (delete-from-queue! q thread)) (thread-queues thread))
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(set-thread-queues! thread #f)
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thread))
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(define (remove-thread-from-queues! thread)
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(if (thread-queues thread)
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(begin
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(for-each (lambda (q) (delete-from-queue! q thread)) (thread-queues thread))
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(set-thread-queues! thread #f))))
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;----------------
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(define current-thread (structure-ref primitives current-thread))
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(define set-current-thread! (structure-ref primitives set-current-thread!))
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; Return values for RUN.
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(define-enumeration event-type
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;; Reason Additional return values
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(
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;; events relating to the running thread
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out-of-time
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completed ; . <results>
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blocked
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killed
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upcall ; <args> unknown upcalls are passed up
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;; asynchronous events
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runnable ; <thread> <args> <thread> is now runnable
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spawned ; <thunk> <id> ... spawn <thunk> as a new thread
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narrowed ; <thunk> <id> ... narrow to <thunk> as a new thread
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interrupt ; <type> . <stuff> an interrupt has occured
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deadlock ; no one can run
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no-event ; there are no pending events
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))
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; DEADLOCK is used by the REPL to gain control when the thread system deadlocks.
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; (RUN <thread> <time>) -> <time-left> <event-type> . <stuff>
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;
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; Run <thread> for no more than <time>. The call returns when the thread
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; stops, returning the remaining time, the reason the thread stopped, and
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; any addition information relating to the reason. Times are in milliseconds.
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;
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; What this does:
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; 1. Check that THREAD is runnable, that it belongs to the current thread,
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; and that it can accept any values being returned.
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; 2. Return immediately if an event is pending.
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; 3. Otherwise suspend the current thread, make THREAD its task, and then
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; run THREAD (or the thread that it is running or ...)
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(define (run thread time)
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(disable-interrupts!)
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(let ((scheduler (current-thread)))
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(cond ((not (thread-continuation thread))
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(enable-interrupts!)
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(error "RUN called with a completed thread" thread))
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((not (eq? (thread-scheduler thread) scheduler))
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(enable-interrupts!)
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(error "thread run by wrong scheduler" thread scheduler))
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((thread-queues thread)
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(enable-interrupts!)
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(apply debug-message (list "thread run while still on a queue "
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(thread-uid thread)
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(thread-name thread)
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(thread-queues thread)))
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(error "thread run while still on a queue" thread))
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((and (thread-current-task thread)
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(not (null? (thread-arguments thread))))
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(enable-interrupts!)
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(error "returning values to running thread"
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thread
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(thread-arguments thread)))
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((event-pending?)
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(enable-interrupts!)
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(apply values time (dequeue! (thread-events (current-thread)))))
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(else
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(set-thread-current-task! scheduler thread)
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(find-and-run-next-thread thread time)))))
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; The next thread to run is the scheduler of the highest thread in the chain
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; with no time left or, if there is no such thread, the bottom thread in the
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; chain. The time limit is the minimum of the remaining times of threads
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; above the thread to be run.
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;
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; We first go down from the user-provided thread, looking for a thread with
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; no time left. We then continue either with that thread's scheduler or with
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; the bottom thread of the chain.
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; This could be modified to add the current time to NEW-THREAD and any threads
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; below. Then the old time limit could be reused if none of the new threads
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; got less time than SCHEDULER and above. This is slower and simpler.
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(define (find-and-run-next-thread new-thread time)
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(set-thread-time! new-thread time) ; in case we don't run it now
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(let loop ((thread new-thread) (time time))
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(let ((next (thread-current-task thread)))
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(if (and next
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(< 0 (thread-time next)))
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(loop next (min time (thread-time next)))
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(debit-thread-times-and-run! thread time)))))
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; Debit the times of all threads from the current-thread on up. If we find a
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; thread with no time left, then that thread's scheduler becomes the potential
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; next thread.
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;
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; Only the root thread can end up with a time-limit of #f, as all other threads
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; have schedulers.
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(define (debit-thread-times-and-run! next-to-run time-limit)
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(let ((elapsed (interrupt-timer-time)))
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(let loop ((thread (current-thread))
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(time-limit time-limit)
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(next-to-run next-to-run))
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(let ((scheduler (thread-scheduler thread)))
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(cond (scheduler
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(let ((time-left (- (thread-time thread) elapsed)))
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(set-thread-time! thread time-left)
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(if (<= time-left 0)
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(loop scheduler #f scheduler)
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(loop scheduler
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(if time-limit
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(min time-limit time-left)
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time-left)
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next-to-run))))
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(next-to-run
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(run-next-thread next-to-run time-limit))
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(else
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(schedule-interrupt! time-limit)))))))
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; Debit the times of all running threads and run whomever is next.
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(define (handle-timer-interrupt interrupted-template ei)
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(if (thread-scheduler (current-thread))
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(debit-thread-times-and-run! #f #f)))
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; Run the next thread, first scheduling an interrupt if the thread is not the
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; root thread. If the next thread has a current task, then the return values
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; are the normal out-of-time values. The bottom thread of the chain gets
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; whatever return values have been stashed earlier.
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(define (run-next-thread thread time-limit)
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(if time-limit (schedule-interrupt! time-limit))
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(let ((arguments (if (thread-current-task thread)
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(list 0 (enum event-type out-of-time))
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(thread-arguments thread))))
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(set-thread-arguments! thread '())
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(switch-to-thread thread arguments)))
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; Fast binary version of MIN
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(define (min x y)
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(if (< x y) x y))
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;----------------
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; Save the current thread and start running NEW-THREAD.
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(define (switch-to-thread thread return-values)
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(primitive-cwcc
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(lambda (cont)
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(set-thread-continuation! (current-thread) cont)
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(run-thread thread return-values))))
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; Start running THREAD. This assumes that THREAD has already been linked into
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; the list of running threads.
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(define (run-thread thread return-values)
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(set-current-thread! thread)
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(set-thread-current-task! thread #f)
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(with-continuation (thread-continuation thread)
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(lambda ()
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(set-thread-continuation! thread #f) ; HCC: for GC
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(enable-interrupts!)
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(apply values return-values))))
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;----------------
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; (SUSPEND <reason> <stuff>) stops the current thread and returns from
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; the call to RUN that invoked it. The arguments passed to SUSPEND become
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; the return values of the call to RUN. SUSPEND itself returns the arguments
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; passed to RUN when the stopped thread is restarted.
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(define (suspend reason stuff)
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(disable-interrupts!)
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(suspend-to (thread-scheduler (current-thread))
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(cons reason stuff)))
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; Stop running the current thread and return from the RUN call in
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; SCHEDULER with the given reason. We need to debit the time of every
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; thread between the current one and SCHEDULER.
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(define (suspend-to scheduler event) ; called with interrupts disabled
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(debit-down! (thread-current-task scheduler))
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(switch-to-thread scheduler
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(cons (thread-time (thread-current-task scheduler))
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event)))
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(define (debit-down! thread)
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(let ((elapsed (interrupt-timer-time)))
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(let loop ((thread thread))
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(if thread
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(begin
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(set-thread-time! thread (- (thread-time thread) elapsed))
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(loop (thread-current-task thread)))))))
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; Same thing, except that we don't save the current continuation and
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; we don't need to debit the thread's time. This is used for completed
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; and killed threads and is not exported.
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(define (exit reason stuff)
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(disable-interrupts!)
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(let ((thread (current-thread)))
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(set-thread-continuation! thread #f)
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(run-thread (thread-scheduler thread)
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(cons (- (thread-time thread)
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(interrupt-timer-time))
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(cons reason stuff)))))
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; Wait for something to happen. If an event is pending we return immediately.
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; Another same thing, except that we have to be careful because we need to
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; set the current thread's time field to a non-integer.
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(define (wait)
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(let ((interrupts (set-enabled-interrupts! no-interrupts)))
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(let ((thread (current-thread)))
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(if (not (and (thread-events thread)
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(not (queue-empty? (thread-events thread)))))
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(let ((time-left (- (thread-time thread)
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(interrupt-timer-time))))
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(set-thread-time! thread 'waiting)
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(switch-to-thread (thread-scheduler thread)
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(list time-left (enum event-type blocked)))))
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(set-enabled-interrupts! interrupts))))
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; Is THREAD waiting for something to happen.
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(define (waiting? thread)
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(eq? (thread-time thread) 'waiting))
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; Various calls to SUSPEND.
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(define (block)
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(suspend (enum event-type blocked) '()))
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(define (relinquish-timeslice)
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(suspend (enum event-type out-of-time) '()))
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; Send the upcall to the current scheduler and check the return value(s)
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; to see if it was handled properly.
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(define (upcall token . args)
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(propogate-upcall (current-thread) token args))
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; Send the upcall to the current thread's handler, if it has one.
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(define (propogate-upcall thread token args)
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(if (thread-scheduler (current-thread))
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(suspend (enum event-type upcall) (list thread token args))
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(begin
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(interrupt-thread thread
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(lambda ()
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(apply error "unhandled upcall" token args)))
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(values))))
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(define (kill-thread! thread) ; dangerous!
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(interrupt-thread thread
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(lambda ignored
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(exit (enum event-type killed) '()))))
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;----------------
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; Make THREAD execute PROC the next time it is run. The thread's own
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; continuation is passed whatever PROC returns.
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(define (interrupt-thread thread proc)
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(let ((interrupts (set-enabled-interrupts! no-interrupts)))
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(cond ((and (thread? thread)
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(not (running? thread)))
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(set-thread-continuation!
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thread
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(compose-continuation proc (thread-continuation thread)))
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(set-enabled-interrupts! interrupts))
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(else
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(set-enabled-interrupts! interrupts)
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(call-error "invalid argument" interrupt-thread thread)))))
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;----------------
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; Dealing with event queues
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; Returns the next event scheduled for the current thread.
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(define (get-next-event!)
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(let* ((interrupts (disable-interrupts!))
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(events (thread-events (current-thread))))
|
|
(if (or (not events)
|
|
(queue-empty? events))
|
|
(begin
|
|
(set-enabled-interrupts! interrupts)
|
|
(enum event-type no-event))
|
|
(let ((event (dequeue! events)))
|
|
(set-enabled-interrupts! interrupts)
|
|
(apply values event)))))
|
|
|
|
(define (event-pending?)
|
|
(let ((events (thread-events (current-thread))))
|
|
(and events (not (queue-empty? events)))))
|
|
|
|
; Schedule the given event for THREAD. If THREAD is waiting, a RUNNABLE
|
|
; event is also scheduled for its scheduler and so on up the tree. If
|
|
; THREAD is running we suspend to allow the interrupt to be processed
|
|
; immediately (running threads that are not the current thread must be
|
|
; above the current thread in the tree and so have priority over it).
|
|
|
|
(define (schedule-event thread . event)
|
|
(let ((interrupts (disable-interrupts!)))
|
|
(cond ((eq? thread (current-thread))
|
|
(add-event! thread event)
|
|
(values))
|
|
((waiting? thread)
|
|
(add-event! thread event)
|
|
(schedule-wakeup thread))
|
|
((running? thread)
|
|
(suspend-to thread event))
|
|
((thread-current-task thread)
|
|
(set-thread-arguments! thread
|
|
(cons (thread-time (thread-current-task thread))
|
|
event))
|
|
(set-thread-current-task! thread #f))
|
|
(else
|
|
(add-event! thread event)))
|
|
(set-enabled-interrupts! interrupts)
|
|
((structure-ref primitives unspecific))))
|
|
|
|
; Make THREAD's scheduler aware of the fact that THREAD is runnable, and
|
|
; similarly for its own scheduler and so on up the tree.
|
|
; Called with interrupts disabled.
|
|
|
|
(define (schedule-wakeup thread)
|
|
(set-thread-time! thread 0) ; clear WAITING flag
|
|
(let ((scheduler (thread-scheduler thread)))
|
|
(if scheduler
|
|
(let ((event (list (enum event-type runnable) thread)))
|
|
(cond ((eq? scheduler (current-thread))
|
|
(add-event! scheduler event)
|
|
(values))
|
|
((waiting? scheduler)
|
|
(add-event! scheduler event)
|
|
(schedule-wakeup scheduler))
|
|
((running? scheduler)
|
|
(suspend-to scheduler event)))))))
|
|
|
|
; Debugging routine
|
|
|
|
(define (show-running)
|
|
(apply debug-message "Running:" (do ((e (current-thread) (thread-scheduler e))
|
|
(l '() (cons (thread-name e)
|
|
(cons " " l))))
|
|
((not e)
|
|
(reverse l)))))
|
|
|
|
; Walk up the scheduler pointers from the current thread to see if THREAD is
|
|
; running.
|
|
|
|
(define (running? thread)
|
|
(let loop ((running (current-thread)))
|
|
(cond ((not running)
|
|
#f)
|
|
((eq? running thread)
|
|
#t)
|
|
(else
|
|
(loop (thread-scheduler running))))))
|
|
|
|
; Spawn a new thread either on the current thread's scheduler or on a specific
|
|
; scheduler.
|
|
|
|
(define (spawn thunk . id)
|
|
(apply spawn-on-scheduler (thread-scheduler (current-thread)) thunk id))
|
|
|
|
(define (spawn-on-root thunk . id)
|
|
(if (root-scheduler)
|
|
(apply spawn-on-scheduler
|
|
(root-scheduler)
|
|
thunk
|
|
id)
|
|
(thunk)))
|
|
|
|
(define (spawn-on-scheduler scheduler thunk . id)
|
|
(schedule-event scheduler
|
|
(enum event-type spawned)
|
|
thunk
|
|
(if (null? id) #f (car id))))
|
|
|
|
(define (narrow thunk . id)
|
|
(schedule-event (thread-scheduler (current-thread))
|
|
(enum event-type narrowed)
|
|
thunk
|
|
(if (null? id) #f (car id))))
|
|
|
|
; Enqueue a RUNNABLE for THREAD's scheduler.
|
|
|
|
(define (make-ready thread . args)
|
|
(if (thread-queues thread)
|
|
(error "trying to schedule a queued thread" thread))
|
|
; (if (not (null? (thread-arguments thread)))
|
|
; (error "trying to replace thread arguments"))
|
|
(set-thread-arguments! thread args)
|
|
(if (thread-scheduler thread)
|
|
(schedule-event (thread-scheduler thread)
|
|
(enum event-type runnable)
|
|
thread)
|
|
(error "MAKE-READY thread has no scheduler" thread)))
|
|
|
|
;----------------
|
|
|
|
(define (schedule-interrupt! time)
|
|
(schedule-interrupt time))
|
|
|
|
(define (cancel-timer-interrupt!)
|
|
(schedule-interrupt 0))
|
|
|
|
; Use CHEAP-TIME to save the cost of a system call on every context switch.
|
|
; This clock is reset whenever we request an interrupt.
|
|
|
|
(define (interrupt-timer-time)
|
|
((structure-ref primitives time) (enum time-option cheap-time) #f))
|
|
|
|
; Used for waking sleepers
|
|
|
|
(define (real-time)
|
|
((structure-ref primitives time) (enum time-option real-time) #f))
|
|
|
|
; Install our own handler for timer interrupts and then start running threads.
|
|
|
|
(define (with-threads thunk)
|
|
(with-interrupts-inhibited
|
|
(lambda ()
|
|
(dynamic-wind
|
|
(lambda ()
|
|
(set-interrupt-handler! (enum interrupt alarm)
|
|
handle-timer-interrupt))
|
|
(lambda ()
|
|
(start-multitasking thunk))
|
|
(lambda ()
|
|
(cancel-timer-interrupt!))))))
|
|
|
|
; Add handler for deadlock and termination and morph ourselves into the
|
|
; initial thread.
|
|
|
|
(define (start-multitasking thunk)
|
|
(call-with-current-continuation
|
|
(lambda (exit-multitasking)
|
|
(with-handler
|
|
(lambda (c punt)
|
|
(if (deadlock? c) (exit-multitasking 0) (punt)))
|
|
(lambda ()
|
|
(call-with-current-continuation
|
|
(lambda (terminate)
|
|
(with-handler (lambda (c punt)
|
|
(if (terminate? c) (terminate 0) (punt)))
|
|
(lambda ()
|
|
(set! *thread-uid* 0)
|
|
(let ((thread (make-thread #f ; thunk
|
|
(get-dynamic-env)
|
|
'initial-thread)))
|
|
(set-thread-scheduler! thread #f)
|
|
(set-thread-time! thread #f)
|
|
(set-thread-dynamic-point! thread (get-dynamic-point))
|
|
(set-current-thread! thread)
|
|
(session-data-set! root-scheduler-slot thread))
|
|
;; End the LET to get THREAD out of the continuation to THUNK
|
|
;; Interrupts were turned off by START-THREADS
|
|
(enable-interrupts!)
|
|
;; We throw out after THUNK to avoid teh EXIT below, as we
|
|
;; have no scheduler to exit to.
|
|
(exit-multitasking (thunk))))))
|
|
;; land here when terminating a thread
|
|
(exit (enum event-type completed) '()))))))
|
|
|
|
; Raised when there is nothing to run.
|
|
|
|
(define-condition-type 'deadlock '())
|
|
(define deadlock? (condition-predicate 'deadlock))
|
|
|
|
; Raised when the current thread has been killed.
|
|
|
|
(define-condition-type 'terminate '())
|
|
(define terminate? (condition-predicate 'terminate))
|
|
|
|
; Kill the current thread. DEBUG-MESSAGE is used to try and make sure that some
|
|
; record exists when an error occured. The system may be too broken for ERROR
|
|
; to work properly.
|
|
|
|
(define (terminate-current-thread)
|
|
(signal 'terminate)
|
|
(debug-message "Can't terminate current thread "
|
|
(thread-uid (current-thread))
|
|
" "
|
|
(thread-name (current-thread)))
|
|
(error "can't terminate current thread")
|
|
0) ; suppress bogus compiler warning
|
|
|
|
|
|
;----------------
|
|
; A slot in the session data to hold the root thread.
|
|
|
|
(define root-scheduler-slot (make-session-data-slot! #f))
|
|
|
|
(define (root-scheduler)
|
|
(session-data-ref root-scheduler-slot))
|
|
|
|
|