+ /* Count the run queue */
+ while (n > 0 && tso != END_TSO_QUEUE) {
+ tso = tso->link;
+ n--;
+ }
+
+ for (; n > 0; n--) {
+ StgClosure *spark;
+ spark = findSpark(rtsFalse);
+ if (spark == NULL) {
+ break; /* no more sparks in the pool */
+ } else {
+ /* I'd prefer this to be done in activateSpark -- HWL */
+ /* tricky - it needs to hold the scheduler lock and
+ * not try to re-acquire it -- SDM */
+ createSparkThread(spark);
+ IF_DEBUG(scheduler,
+ sched_belch("==^^ turning spark of closure %p into a thread",
+ (StgClosure *)spark));
+ }
+ }
+ /* We need to wake up the other tasks if we just created some
+ * work for them.
+ */
+ if (getFreeCapabilities() - n > 1) {
+ signalCondition( &thread_ready_cond );
+ }
+ }
+#endif // SMP
+
+ /* check for signals each time around the scheduler */
+#ifndef mingw32_TARGET_OS
+ if (signals_pending()) {
+ RELEASE_LOCK(&sched_mutex); /* ToDo: kill */
+ startSignalHandlers();
+ ACQUIRE_LOCK(&sched_mutex);
+ }
+#endif
+
+ /* Check whether any waiting threads need to be woken up. If the
+ * run queue is empty, and there are no other tasks running, we
+ * can wait indefinitely for something to happen.
+ * ToDo: what if another client comes along & requests another
+ * main thread?
+ */
+ if ( !EMPTY_QUEUE(blocked_queue_hd) || !EMPTY_QUEUE(sleeping_queue) ) {
+ awaitEvent( EMPTY_RUN_QUEUE()
+#if defined(SMP)
+ && allFreeCapabilities()
+#endif
+ );
+ }
+ /* we can be interrupted while waiting for I/O... */
+ if (interrupted) continue;
+
+ /*
+ * Detect deadlock: when we have no threads to run, there are no
+ * threads waiting on I/O or sleeping, and all the other tasks are
+ * waiting for work, we must have a deadlock of some description.
+ *
+ * We first try to find threads blocked on themselves (ie. black
+ * holes), and generate NonTermination exceptions where necessary.
+ *
+ * If no threads are black holed, we have a deadlock situation, so
+ * inform all the main threads.
+ */
+#ifndef PAR
+ if ( EMPTY_THREAD_QUEUES()
+#if defined(RTS_SUPPORTS_THREADS)
+ && EMPTY_QUEUE(suspended_ccalling_threads)
+#endif
+#ifdef SMP
+ && allFreeCapabilities()
+#endif
+ )
+ {
+ IF_DEBUG(scheduler, sched_belch("deadlocked, forcing major GC..."));
+#if defined(THREADED_RTS)
+ /* and SMP mode ..? */
+ releaseCapability(cap);
+#endif
+ // Garbage collection can release some new threads due to
+ // either (a) finalizers or (b) threads resurrected because
+ // they are about to be send BlockedOnDeadMVar. Any threads
+ // thus released will be immediately runnable.
+ GarbageCollect(GetRoots,rtsTrue);
+
+ if ( !EMPTY_RUN_QUEUE() ) { goto not_deadlocked; }
+
+ IF_DEBUG(scheduler,
+ sched_belch("still deadlocked, checking for black holes..."));
+ detectBlackHoles();
+
+ if ( !EMPTY_RUN_QUEUE() ) { goto not_deadlocked; }
+
+#ifndef mingw32_TARGET_OS
+ /* If we have user-installed signal handlers, then wait
+ * for signals to arrive rather then bombing out with a
+ * deadlock.
+ */
+#if defined(RTS_SUPPORTS_THREADS)
+ if ( 0 ) { /* hmm..what to do? Simply stop waiting for
+ a signal with no runnable threads (or I/O
+ suspended ones) leads nowhere quick.
+ For now, simply shut down when we reach this
+ condition.
+
+ ToDo: define precisely under what conditions
+ the Scheduler should shut down in an MT setting.
+ */
+#else
+ if ( anyUserHandlers() ) {
+#endif
+ IF_DEBUG(scheduler,
+ sched_belch("still deadlocked, waiting for signals..."));
+
+ awaitUserSignals();
+
+ // we might be interrupted...
+ if (interrupted) { continue; }
+
+ if (signals_pending()) {
+ RELEASE_LOCK(&sched_mutex);
+ startSignalHandlers();
+ ACQUIRE_LOCK(&sched_mutex);
+ }
+ ASSERT(!EMPTY_RUN_QUEUE());
+ goto not_deadlocked;
+ }
+#endif
+
+ /* Probably a real deadlock. Send the current main thread the
+ * Deadlock exception (or in the SMP build, send *all* main
+ * threads the deadlock exception, since none of them can make
+ * progress).
+ */
+ {
+ StgMainThread *m;
+#if defined(RTS_SUPPORTS_THREADS)
+ for (m = main_threads; m != NULL; m = m->link) {
+ switch (m->tso->why_blocked) {
+ case BlockedOnBlackHole:
+ raiseAsync(m->tso, (StgClosure *)NonTermination_closure);
+ break;
+ case BlockedOnException:
+ case BlockedOnMVar:
+ raiseAsync(m->tso, (StgClosure *)Deadlock_closure);
+ break;
+ default:
+ barf("deadlock: main thread blocked in a strange way");
+ }
+ }
+#else
+ m = main_threads;
+ switch (m->tso->why_blocked) {
+ case BlockedOnBlackHole:
+ raiseAsync(m->tso, (StgClosure *)NonTermination_closure);
+ break;
+ case BlockedOnException:
+ case BlockedOnMVar:
+ raiseAsync(m->tso, (StgClosure *)Deadlock_closure);
+ break;
+ default:
+ barf("deadlock: main thread blocked in a strange way");
+ }
+#endif
+ }
+
+#if defined(RTS_SUPPORTS_THREADS)
+ /* ToDo: revisit conditions (and mechanism) for shutting
+ down a multi-threaded world */
+ IF_DEBUG(scheduler, sched_belch("all done, i think...shutting down."));
+ RELEASE_LOCK(&sched_mutex);
+ shutdownHaskell();
+ return;
+#endif
+ }
+ not_deadlocked:
+
+#elif defined(PAR)
+ /* ToDo: add deadlock detection in GUM (similar to SMP) -- HWL */
+#endif
+
+#if defined(SMP)
+ /* If there's a GC pending, don't do anything until it has
+ * completed.
+ */
+ if (ready_to_gc) {
+ IF_DEBUG(scheduler,sched_belch("waiting for GC"));
+ waitCondition( &gc_pending_cond, &sched_mutex );
+ }
+#endif
+
+#if defined(RTS_SUPPORTS_THREADS)
+ /* block until we've got a thread on the run queue and a free
+ * capability.
+ *
+ */
+ if ( EMPTY_RUN_QUEUE() ) {
+ /* Give up our capability */
+ releaseCapability(cap);
+
+ /* If we're in the process of shutting down (& running the
+ * a batch of finalisers), don't wait around.
+ */
+ if ( shutting_down_scheduler ) {
+ RELEASE_LOCK(&sched_mutex);
+ return;
+ }
+ IF_DEBUG(scheduler, sched_belch("thread %d: waiting for work", osThreadId()));
+ waitForWorkCapability(&sched_mutex, &cap, rtsTrue);
+ IF_DEBUG(scheduler, sched_belch("thread %d: work now available", osThreadId()));
+ }
+#endif
+
+#if defined(GRAN)
+ if (RtsFlags.GranFlags.Light)
+ GranSimLight_enter_system(event, &ActiveTSO); // adjust ActiveTSO etc
+
+ /* adjust time based on time-stamp */
+ if (event->time > CurrentTime[CurrentProc] &&
+ event->evttype != ContinueThread)
+ CurrentTime[CurrentProc] = event->time;
+
+ /* Deal with the idle PEs (may issue FindWork or MoveSpark events) */
+ if (!RtsFlags.GranFlags.Light)
+ handleIdlePEs();
+
+ IF_DEBUG(gran, fprintf(stderr, "GRAN: switch by event-type\n"));
+
+ /* main event dispatcher in GranSim */
+ switch (event->evttype) {
+ /* Should just be continuing execution */
+ case ContinueThread:
+ IF_DEBUG(gran, fprintf(stderr, "GRAN: doing ContinueThread\n"));
+ /* ToDo: check assertion
+ ASSERT(run_queue_hd != (StgTSO*)NULL &&
+ run_queue_hd != END_TSO_QUEUE);
+ */
+ /* Ignore ContinueThreads for fetching threads (if synchr comm) */
+ if (!RtsFlags.GranFlags.DoAsyncFetch &&
+ procStatus[CurrentProc]==Fetching) {
+ belch("ghuH: Spurious ContinueThread while Fetching ignored; TSO %d (%p) [PE %d]",
+ CurrentTSO->id, CurrentTSO, CurrentProc);
+ goto next_thread;
+ }
+ /* Ignore ContinueThreads for completed threads */
+ if (CurrentTSO->what_next == ThreadComplete) {
+ belch("ghuH: found a ContinueThread event for completed thread %d (%p) [PE %d] (ignoring ContinueThread)",
+ CurrentTSO->id, CurrentTSO, CurrentProc);
+ goto next_thread;
+ }
+ /* Ignore ContinueThreads for threads that are being migrated */
+ if (PROCS(CurrentTSO)==Nowhere) {
+ belch("ghuH: trying to run the migrating TSO %d (%p) [PE %d] (ignoring ContinueThread)",
+ CurrentTSO->id, CurrentTSO, CurrentProc);
+ goto next_thread;
+ }
+ /* The thread should be at the beginning of the run queue */
+ if (CurrentTSO!=run_queue_hds[CurrentProc]) {
+ belch("ghuH: TSO %d (%p) [PE %d] is not at the start of the run_queue when doing a ContinueThread",
+ CurrentTSO->id, CurrentTSO, CurrentProc);
+ break; // run the thread anyway
+ }
+ /*
+ new_event(proc, proc, CurrentTime[proc],
+ FindWork,
+ (StgTSO*)NULL, (StgClosure*)NULL, (rtsSpark*)NULL);
+ goto next_thread;
+ */ /* Catches superfluous CONTINUEs -- should be unnecessary */
+ break; // now actually run the thread; DaH Qu'vam yImuHbej
+
+ case FetchNode:
+ do_the_fetchnode(event);
+ goto next_thread; /* handle next event in event queue */
+
+ case GlobalBlock:
+ do_the_globalblock(event);
+ goto next_thread; /* handle next event in event queue */
+
+ case FetchReply:
+ do_the_fetchreply(event);
+ goto next_thread; /* handle next event in event queue */
+
+ case UnblockThread: /* Move from the blocked queue to the tail of */
+ do_the_unblock(event);
+ goto next_thread; /* handle next event in event queue */
+
+ case ResumeThread: /* Move from the blocked queue to the tail of */
+ /* the runnable queue ( i.e. Qu' SImqa'lu') */
+ event->tso->gran.blocktime +=
+ CurrentTime[CurrentProc] - event->tso->gran.blockedat;
+ do_the_startthread(event);
+ goto next_thread; /* handle next event in event queue */
+
+ case StartThread:
+ do_the_startthread(event);
+ goto next_thread; /* handle next event in event queue */
+
+ case MoveThread:
+ do_the_movethread(event);
+ goto next_thread; /* handle next event in event queue */
+
+ case MoveSpark:
+ do_the_movespark(event);
+ goto next_thread; /* handle next event in event queue */
+
+ case FindWork:
+ do_the_findwork(event);
+ goto next_thread; /* handle next event in event queue */
+
+ default:
+ barf("Illegal event type %u\n", event->evttype);
+ } /* switch */
+
+ /* This point was scheduler_loop in the old RTS */
+
+ IF_DEBUG(gran, belch("GRAN: after main switch"));
+
+ TimeOfLastEvent = CurrentTime[CurrentProc];
+ TimeOfNextEvent = get_time_of_next_event();
+ IgnoreEvents=(TimeOfNextEvent==0); // HWL HACK
+ // CurrentTSO = ThreadQueueHd;
+
+ IF_DEBUG(gran, belch("GRAN: time of next event is: %ld",
+ TimeOfNextEvent));
+
+ if (RtsFlags.GranFlags.Light)
+ GranSimLight_leave_system(event, &ActiveTSO);
+
+ EndOfTimeSlice = CurrentTime[CurrentProc]+RtsFlags.GranFlags.time_slice;
+
+ IF_DEBUG(gran,
+ belch("GRAN: end of time-slice is %#lx", EndOfTimeSlice));
+
+ /* in a GranSim setup the TSO stays on the run queue */
+ t = CurrentTSO;
+ /* Take a thread from the run queue. */
+ t = POP_RUN_QUEUE(); // take_off_run_queue(t);
+
+ IF_DEBUG(gran,
+ fprintf(stderr, "GRAN: About to run current thread, which is\n");
+ G_TSO(t,5));
+
+ context_switch = 0; // turned on via GranYield, checking events and time slice
+
+ IF_DEBUG(gran,
+ DumpGranEvent(GR_SCHEDULE, t));
+
+ procStatus[CurrentProc] = Busy;
+
+#elif defined(PAR)
+ if (PendingFetches != END_BF_QUEUE) {
+ processFetches();
+ }
+
+ /* ToDo: phps merge with spark activation above */
+ /* check whether we have local work and send requests if we have none */
+ if (EMPTY_RUN_QUEUE()) { /* no runnable threads */
+ /* :-[ no local threads => look out for local sparks */
+ /* the spark pool for the current PE */
+ pool = &(MainRegTable.rSparks); // generalise to cap = &MainRegTable
+ if (advisory_thread_count < RtsFlags.ParFlags.maxThreads &&
+ pool->hd < pool->tl) {
+ /*
+ * ToDo: add GC code check that we really have enough heap afterwards!!
+ * Old comment:
+ * If we're here (no runnable threads) and we have pending
+ * sparks, we must have a space problem. Get enough space
+ * to turn one of those pending sparks into a
+ * thread...
+ */
+
+ spark = findSpark(rtsFalse); /* get a spark */
+ if (spark != (rtsSpark) NULL) {
+ tso = activateSpark(spark); /* turn the spark into a thread */
+ IF_PAR_DEBUG(schedule,
+ belch("==== schedule: Created TSO %d (%p); %d threads active",
+ tso->id, tso, advisory_thread_count));
+
+ if (tso==END_TSO_QUEUE) { /* failed to activate spark->back to loop */
+ belch("==^^ failed to activate spark");
+ goto next_thread;
+ } /* otherwise fall through & pick-up new tso */
+ } else {
+ IF_PAR_DEBUG(verbose,
+ belch("==^^ no local sparks (spark pool contains only NFs: %d)",
+ spark_queue_len(pool)));
+ goto next_thread;
+ }
+ }
+
+ /* If we still have no work we need to send a FISH to get a spark
+ from another PE
+ */
+ if (EMPTY_RUN_QUEUE()) {
+ /* =8-[ no local sparks => look for work on other PEs */
+ /*
+ * We really have absolutely no work. Send out a fish
+ * (there may be some out there already), and wait for
+ * something to arrive. We clearly can't run any threads
+ * until a SCHEDULE or RESUME arrives, and so that's what
+ * we're hoping to see. (Of course, we still have to
+ * respond to other types of messages.)
+ */
+ TIME now = msTime() /*CURRENT_TIME*/;
+ IF_PAR_DEBUG(verbose,
+ belch("-- now=%ld", now));
+ IF_PAR_DEBUG(verbose,
+ if (outstandingFishes < RtsFlags.ParFlags.maxFishes &&
+ (last_fish_arrived_at!=0 &&
+ last_fish_arrived_at+RtsFlags.ParFlags.fishDelay > now)) {
+ belch("--$$ delaying FISH until %ld (last fish %ld, delay %ld, now %ld)",
+ last_fish_arrived_at+RtsFlags.ParFlags.fishDelay,
+ last_fish_arrived_at,
+ RtsFlags.ParFlags.fishDelay, now);
+ });
+
+ if (outstandingFishes < RtsFlags.ParFlags.maxFishes &&
+ (last_fish_arrived_at==0 ||
+ (last_fish_arrived_at+RtsFlags.ParFlags.fishDelay <= now))) {
+ /* outstandingFishes is set in sendFish, processFish;
+ avoid flooding system with fishes via delay */
+ pe = choosePE();
+ sendFish(pe, mytid, NEW_FISH_AGE, NEW_FISH_HISTORY,
+ NEW_FISH_HUNGER);
+
+ // Global statistics: count no. of fishes
+ if (RtsFlags.ParFlags.ParStats.Global &&
+ RtsFlags.GcFlags.giveStats > NO_GC_STATS) {
+ globalParStats.tot_fish_mess++;
+ }
+ }
+
+ receivedFinish = processMessages();
+ goto next_thread;
+ }
+ } else if (PacketsWaiting()) { /* Look for incoming messages */
+ receivedFinish = processMessages();
+ }
+
+ /* Now we are sure that we have some work available */
+ ASSERT(run_queue_hd != END_TSO_QUEUE);
+
+ /* Take a thread from the run queue, if we have work */
+ t = POP_RUN_QUEUE(); // take_off_run_queue(END_TSO_QUEUE);
+ IF_DEBUG(sanity,checkTSO(t));
+
+ /* ToDo: write something to the log-file
+ if (RTSflags.ParFlags.granSimStats && !sameThread)
+ DumpGranEvent(GR_SCHEDULE, RunnableThreadsHd);
+
+ CurrentTSO = t;
+ */
+ /* the spark pool for the current PE */
+ pool = &(MainRegTable.rSparks); // generalise to cap = &MainRegTable
+
+ IF_DEBUG(scheduler,
+ belch("--=^ %d threads, %d sparks on [%#x]",
+ run_queue_len(), spark_queue_len(pool), CURRENT_PROC));
+
+# if 1
+ if (0 && RtsFlags.ParFlags.ParStats.Full &&
+ t && LastTSO && t->id != LastTSO->id &&
+ LastTSO->why_blocked == NotBlocked &&
+ LastTSO->what_next != ThreadComplete) {
+ // if previously scheduled TSO not blocked we have to record the context switch
+ DumpVeryRawGranEvent(TimeOfLastYield, CURRENT_PROC, CURRENT_PROC,
+ GR_DESCHEDULE, LastTSO, (StgClosure *)NULL, 0, 0);
+ }
+
+ if (RtsFlags.ParFlags.ParStats.Full &&
+ (emitSchedule /* forced emit */ ||
+ (t && LastTSO && t->id != LastTSO->id))) {
+ /*
+ we are running a different TSO, so write a schedule event to log file
+ NB: If we use fair scheduling we also have to write a deschedule
+ event for LastTSO; with unfair scheduling we know that the
+ previous tso has blocked whenever we switch to another tso, so
+ we don't need it in GUM for now
+ */
+ DumpRawGranEvent(CURRENT_PROC, CURRENT_PROC,
+ GR_SCHEDULE, t, (StgClosure *)NULL, 0, 0);
+ emitSchedule = rtsFalse;
+ }
+
+# endif
+#else /* !GRAN && !PAR */
+
+ /* grab a thread from the run queue */
+ ASSERT(run_queue_hd != END_TSO_QUEUE);
+ t = POP_RUN_QUEUE();
+ // Sanity check the thread we're about to run. This can be
+ // expensive if there is lots of thread switching going on...
+ IF_DEBUG(sanity,checkTSO(t));
+#endif
+
+ cap->r.rCurrentTSO = t;
+
+ /* context switches are now initiated by the timer signal, unless
+ * the user specified "context switch as often as possible", with
+ * +RTS -C0
+ */
+ if (
+#ifdef PROFILING
+ RtsFlags.ProfFlags.profileInterval == 0 ||
+#endif
+ (RtsFlags.ConcFlags.ctxtSwitchTicks == 0
+ && (run_queue_hd != END_TSO_QUEUE
+ || blocked_queue_hd != END_TSO_QUEUE
+ || sleeping_queue != END_TSO_QUEUE)))
+ context_switch = 1;
+ else
+ context_switch = 0;
+
+ RELEASE_LOCK(&sched_mutex);
+
+ IF_DEBUG(scheduler, sched_belch("-->> Running TSO %ld (%p) %s ...",
+ t->id, t, whatNext_strs[t->what_next]));
+
+#ifdef PROFILING
+ startHeapProfTimer();
+#endif
+
+ /* +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ */
+ /* Run the current thread
+ */
+ switch (cap->r.rCurrentTSO->what_next) {
+ case ThreadKilled:
+ case ThreadComplete:
+ /* Thread already finished, return to scheduler. */
+ ret = ThreadFinished;
+ break;
+ case ThreadEnterGHC:
+ ret = StgRun((StgFunPtr) stg_enterStackTop, &cap->r);
+ break;
+ case ThreadRunGHC:
+ ret = StgRun((StgFunPtr) stg_returnToStackTop, &cap->r);
+ break;
+ case ThreadEnterInterp:
+ ret = interpretBCO(cap);
+ break;
+ default:
+ barf("schedule: invalid what_next field");
+ }
+ /* +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ */
+
+ /* Costs for the scheduler are assigned to CCS_SYSTEM */
+#ifdef PROFILING
+ stopHeapProfTimer();
+ CCCS = CCS_SYSTEM;
+#endif
+
+ ACQUIRE_LOCK(&sched_mutex);
+
+#ifdef SMP
+ IF_DEBUG(scheduler,fprintf(stderr,"scheduler (task %ld): ", osThreadId()););
+#elif !defined(GRAN) && !defined(PAR)
+ IF_DEBUG(scheduler,fprintf(stderr,"scheduler: "););
+#endif
+ t = cap->r.rCurrentTSO;
+
+#if defined(PAR)
+ /* HACK 675: if the last thread didn't yield, make sure to print a
+ SCHEDULE event to the log file when StgRunning the next thread, even
+ if it is the same one as before */
+ LastTSO = t;
+ TimeOfLastYield = CURRENT_TIME;
+#endif
+
+ switch (ret) {
+ case HeapOverflow:
+#if defined(GRAN)
+ IF_DEBUG(gran, DumpGranEvent(GR_DESCHEDULE, t));
+ globalGranStats.tot_heapover++;
+#elif defined(PAR)
+ globalParStats.tot_heapover++;
+#endif
+
+ // did the task ask for a large block?
+ if (cap->r.rHpAlloc > BLOCK_SIZE_W) {
+ // if so, get one and push it on the front of the nursery.
+ bdescr *bd;
+ nat blocks;
+
+ blocks = (nat)BLOCK_ROUND_UP(cap->r.rHpAlloc * sizeof(W_)) / BLOCK_SIZE;
+
+ IF_DEBUG(scheduler,belch("--<< thread %ld (%p; %s) stopped: requesting a large block (size %d)",
+ t->id, t,
+ whatNext_strs[t->what_next], blocks));
+
+ // don't do this if it would push us over the
+ // alloc_blocks_lim limit; we'll GC first.
+ if (alloc_blocks + blocks < alloc_blocks_lim) {
+
+ alloc_blocks += blocks;
+ bd = allocGroup( blocks );
+
+ // link the new group into the list
+ bd->link = cap->r.rCurrentNursery;
+ bd->u.back = cap->r.rCurrentNursery->u.back;
+ if (cap->r.rCurrentNursery->u.back != NULL) {
+ cap->r.rCurrentNursery->u.back->link = bd;
+ } else {
+ ASSERT(g0s0->blocks == cap->r.rCurrentNursery &&
+ g0s0->blocks == cap->r.rNursery);
+ cap->r.rNursery = g0s0->blocks = bd;
+ }
+ cap->r.rCurrentNursery->u.back = bd;
+
+ // initialise it as a nursery block. We initialise the
+ // step, gen_no, and flags field of *every* sub-block in
+ // this large block, because this is easier than making
+ // sure that we always find the block head of a large
+ // block whenever we call Bdescr() (eg. evacuate() and
+ // isAlive() in the GC would both have to do this, at
+ // least).
+ {
+ bdescr *x;
+ for (x = bd; x < bd + blocks; x++) {
+ x->step = g0s0;
+ x->gen_no = 0;
+ x->flags = 0;
+ x->free = x->start;
+ }
+ }
+
+ // don't forget to update the block count in g0s0.
+ g0s0->n_blocks += blocks;
+ ASSERT(countBlocks(g0s0->blocks) == g0s0->n_blocks);
+
+ // now update the nursery to point to the new block
+ cap->r.rCurrentNursery = bd;
+
+ // we might be unlucky and have another thread get on the
+ // run queue before us and steal the large block, but in that
+ // case the thread will just end up requesting another large
+ // block.
+ PUSH_ON_RUN_QUEUE(t);
+ break;
+ }
+ }
+
+ /* make all the running tasks block on a condition variable,
+ * maybe set context_switch and wait till they all pile in,
+ * then have them wait on a GC condition variable.
+ */
+ IF_DEBUG(scheduler,belch("--<< thread %ld (%p; %s) stopped: HeapOverflow",
+ t->id, t, whatNext_strs[t->what_next]));
+ threadPaused(t);
+#if defined(GRAN)
+ ASSERT(!is_on_queue(t,CurrentProc));
+#elif defined(PAR)
+ /* Currently we emit a DESCHEDULE event before GC in GUM.
+ ToDo: either add separate event to distinguish SYSTEM time from rest
+ or just nuke this DESCHEDULE (and the following SCHEDULE) */
+ if (0 && RtsFlags.ParFlags.ParStats.Full) {
+ DumpRawGranEvent(CURRENT_PROC, CURRENT_PROC,
+ GR_DESCHEDULE, t, (StgClosure *)NULL, 0, 0);
+ emitSchedule = rtsTrue;
+ }
+#endif
+
+ ready_to_gc = rtsTrue;
+ context_switch = 1; /* stop other threads ASAP */
+ PUSH_ON_RUN_QUEUE(t);
+ /* actual GC is done at the end of the while loop */
+ break;
+
+ case StackOverflow:
+#if defined(GRAN)
+ IF_DEBUG(gran,
+ DumpGranEvent(GR_DESCHEDULE, t));
+ globalGranStats.tot_stackover++;
+#elif defined(PAR)
+ // IF_DEBUG(par,
+ // DumpGranEvent(GR_DESCHEDULE, t);
+ globalParStats.tot_stackover++;
+#endif
+ IF_DEBUG(scheduler,belch("--<< thread %ld (%p; %s) stopped, StackOverflow",
+ t->id, t, whatNext_strs[t->what_next]));
+ /* just adjust the stack for this thread, then pop it back
+ * on the run queue.
+ */
+ threadPaused(t);
+ {
+ StgMainThread *m;
+ /* enlarge the stack */
+ StgTSO *new_t = threadStackOverflow(t);
+
+ /* This TSO has moved, so update any pointers to it from the
+ * main thread stack. It better not be on any other queues...
+ * (it shouldn't be).
+ */
+ for (m = main_threads; m != NULL; m = m->link) {
+ if (m->tso == t) {
+ m->tso = new_t;
+ }
+ }
+ threadPaused(new_t);
+ PUSH_ON_RUN_QUEUE(new_t);
+ }
+ break;
+
+ case ThreadYielding:
+#if defined(GRAN)
+ IF_DEBUG(gran,
+ DumpGranEvent(GR_DESCHEDULE, t));
+ globalGranStats.tot_yields++;
+#elif defined(PAR)
+ // IF_DEBUG(par,
+ // DumpGranEvent(GR_DESCHEDULE, t);
+ globalParStats.tot_yields++;
+#endif
+ /* put the thread back on the run queue. Then, if we're ready to
+ * GC, check whether this is the last task to stop. If so, wake
+ * up the GC thread. getThread will block during a GC until the
+ * GC is finished.
+ */
+ IF_DEBUG(scheduler,
+ if (t->what_next == ThreadEnterInterp) {
+ /* ToDo: or maybe a timer expired when we were in Hugs?
+ * or maybe someone hit ctrl-C
+ */
+ belch("--<< thread %ld (%p; %s) stopped to switch to Hugs",
+ t->id, t, whatNext_strs[t->what_next]);
+ } else {
+ belch("--<< thread %ld (%p; %s) stopped, yielding",
+ t->id, t, whatNext_strs[t->what_next]);
+ }
+ );
+
+ threadPaused(t);
+
+ IF_DEBUG(sanity,
+ //belch("&& Doing sanity check on yielding TSO %ld.", t->id);
+ checkTSO(t));
+ ASSERT(t->link == END_TSO_QUEUE);
+#if defined(GRAN)
+ ASSERT(!is_on_queue(t,CurrentProc));
+
+ IF_DEBUG(sanity,
+ //belch("&& Doing sanity check on all ThreadQueues (and their TSOs).");
+ checkThreadQsSanity(rtsTrue));
+#endif
+#if defined(PAR)
+ if (RtsFlags.ParFlags.doFairScheduling) {
+ /* this does round-robin scheduling; good for concurrency */
+ APPEND_TO_RUN_QUEUE(t);
+ } else {
+ /* this does unfair scheduling; good for parallelism */
+ PUSH_ON_RUN_QUEUE(t);
+ }
+#else
+ /* this does round-robin scheduling; good for concurrency */
+ APPEND_TO_RUN_QUEUE(t);
+#endif
+#if defined(GRAN)
+ /* add a ContinueThread event to actually process the thread */
+ new_event(CurrentProc, CurrentProc, CurrentTime[CurrentProc],
+ ContinueThread,
+ t, (StgClosure*)NULL, (rtsSpark*)NULL);
+ IF_GRAN_DEBUG(bq,
+ belch("GRAN: eventq and runnableq after adding yielded thread to queue again:");
+ G_EVENTQ(0);
+ G_CURR_THREADQ(0));
+#endif /* GRAN */
+ break;
+
+ case ThreadBlocked:
+#if defined(GRAN)
+ IF_DEBUG(scheduler,
+ belch("--<< thread %ld (%p; %s) stopped, blocking on node %p [PE %d] with BQ: ",
+ t->id, t, whatNext_strs[t->what_next], t->block_info.closure, (t->block_info.closure==(StgClosure*)NULL ? 99 : where_is(t->block_info.closure)));
+ if (t->block_info.closure!=(StgClosure*)NULL) print_bq(t->block_info.closure));
+
+ // ??? needed; should emit block before
+ IF_DEBUG(gran,
+ DumpGranEvent(GR_DESCHEDULE, t));
+ prune_eventq(t, (StgClosure *)NULL); // prune ContinueThreads for t
+ /*
+ ngoq Dogh!
+ ASSERT(procStatus[CurrentProc]==Busy ||
+ ((procStatus[CurrentProc]==Fetching) &&
+ (t->block_info.closure!=(StgClosure*)NULL)));
+ if (run_queue_hds[CurrentProc] == END_TSO_QUEUE &&
+ !(!RtsFlags.GranFlags.DoAsyncFetch &&
+ procStatus[CurrentProc]==Fetching))
+ procStatus[CurrentProc] = Idle;
+ */
+#elif defined(PAR)
+ IF_DEBUG(scheduler,
+ belch("--<< thread %ld (%p; %s) stopped, blocking on node %p with BQ: ",
+ t->id, t, whatNext_strs[t->what_next], t->block_info.closure));
+ IF_PAR_DEBUG(bq,
+
+ if (t->block_info.closure!=(StgClosure*)NULL)
+ print_bq(t->block_info.closure));
+
+ /* Send a fetch (if BlockedOnGA) and dump event to log file */
+ blockThread(t);
+
+ /* whatever we schedule next, we must log that schedule */
+ emitSchedule = rtsTrue;
+
+#else /* !GRAN */
+ /* don't need to do anything. Either the thread is blocked on
+ * I/O, in which case we'll have called addToBlockedQueue
+ * previously, or it's blocked on an MVar or Blackhole, in which
+ * case it'll be on the relevant queue already.
+ */
+ IF_DEBUG(scheduler,
+ fprintf(stderr, "--<< thread %d (%p) stopped: ", t->id, t);
+ printThreadBlockage(t);
+ fprintf(stderr, "\n"));
+
+ /* Only for dumping event to log file
+ ToDo: do I need this in GranSim, too?
+ blockThread(t);
+ */
+#endif
+ threadPaused(t);
+ break;
+
+ case ThreadFinished:
+ /* Need to check whether this was a main thread, and if so, signal
+ * the task that started it with the return value. If we have no
+ * more main threads, we probably need to stop all the tasks until
+ * we get a new one.
+ */
+ /* We also end up here if the thread kills itself with an
+ * uncaught exception, see Exception.hc.
+ */
+ IF_DEBUG(scheduler,belch("--++ thread %d (%p) finished", t->id, t));
+#if defined(GRAN)
+ endThread(t, CurrentProc); // clean-up the thread
+#elif defined(PAR)
+ /* For now all are advisory -- HWL */
+ //if(t->priority==AdvisoryPriority) ??
+ advisory_thread_count--;
+
+# ifdef DIST
+ if(t->dist.priority==RevalPriority)
+ FinishReval(t);
+# endif
+
+ if (RtsFlags.ParFlags.ParStats.Full &&
+ !RtsFlags.ParFlags.ParStats.Suppressed)
+ DumpEndEvent(CURRENT_PROC, t, rtsFalse /* not mandatory */);
+#endif
+ break;
+
+ default:
+ barf("schedule: invalid thread return code %d", (int)ret);
+ }
+
+#ifdef PROFILING
+ if (RtsFlags.ProfFlags.profileInterval==0 || performHeapProfile) {
+ GarbageCollect(GetRoots, rtsTrue);
+ heapCensus();
+ performHeapProfile = rtsFalse;
+ ready_to_gc = rtsFalse; // we already GC'd
+ }
+#endif
+
+ if (ready_to_gc
+#ifdef SMP
+ && allFreeCapabilities()
+#endif
+ ) {
+ /* everybody back, start the GC.
+ * Could do it in this thread, or signal a condition var
+ * to do it in another thread. Either way, we need to
+ * broadcast on gc_pending_cond afterward.
+ */
+#if defined(RTS_SUPPORTS_THREADS)
+ IF_DEBUG(scheduler,sched_belch("doing GC"));
+#endif
+ GarbageCollect(GetRoots,rtsFalse);
+ ready_to_gc = rtsFalse;
+#ifdef SMP
+ broadcastCondition(&gc_pending_cond);
+#endif
+#if defined(GRAN)
+ /* add a ContinueThread event to continue execution of current thread */
+ new_event(CurrentProc, CurrentProc, CurrentTime[CurrentProc],
+ ContinueThread,
+ t, (StgClosure*)NULL, (rtsSpark*)NULL);
+ IF_GRAN_DEBUG(bq,
+ fprintf(stderr, "GRAN: eventq and runnableq after Garbage collection:\n");
+ G_EVENTQ(0);
+ G_CURR_THREADQ(0));
+#endif /* GRAN */
+ }
+
+#if defined(GRAN)
+ next_thread:
+ IF_GRAN_DEBUG(unused,
+ print_eventq(EventHd));
+
+ event = get_next_event();
+#elif defined(PAR)
+ next_thread:
+ /* ToDo: wait for next message to arrive rather than busy wait */
+#endif /* GRAN */
+
+ } /* end of while(1) */
+
+ IF_PAR_DEBUG(verbose,
+ belch("== Leaving schedule() after having received Finish"));
+}
+
+/* ---------------------------------------------------------------------------
+ * Singleton fork(). Do not copy any running threads.
+ * ------------------------------------------------------------------------- */
+
+StgInt forkProcess(StgTSO* tso) {
+
+#ifndef mingw32_TARGET_OS
+ pid_t pid;
+ StgTSO* t,*next;
+ StgMainThread *m;
+ rtsBool doKill;
+
+ IF_DEBUG(scheduler,sched_belch("forking!"));
+
+ pid = fork();
+ if (pid) { /* parent */
+
+ /* just return the pid */
+
+ } else { /* child */
+ /* wipe all other threads */
+ run_queue_hd = run_queue_tl = tso;
+ tso->link = END_TSO_QUEUE;
+
+ /* When clearing out the threads, we need to ensure
+ that a 'main thread' is left behind; if there isn't,
+ the Scheduler will shutdown next time it is entered.
+
+ ==> we don't kill a thread that's on the main_threads
+ list (nor the current thread.)
+
+ [ Attempts at implementing the more ambitious scheme of
+ killing the main_threads also, and then adding the
+ current thread onto the main_threads list if it wasn't
+ there already, failed -- waitThread() (for one) wasn't
+ up to it. If it proves to be desirable to also kill
+ the main threads, then this scheme will have to be
+ revisited (and fully debugged!)
+
+ -- sof 7/2002
+ ]
+ */
+ /* DO NOT TOUCH THE QUEUES directly because most of the code around
+ us is picky about finding the thread still in its queue when
+ handling the deleteThread() */
+
+ for (t = all_threads; t != END_TSO_QUEUE; t = next) {
+ next = t->link;
+
+ /* Don't kill the current thread.. */
+ if (t->id == tso->id) continue;
+ doKill=rtsTrue;
+ /* ..or a main thread */
+ for (m = main_threads; m != NULL; m = m->link) {
+ if (m->tso->id == t->id) {
+ doKill=rtsFalse;
+ break;
+ }
+ }
+ if (doKill) {
+ deleteThread(t);
+ }
+ }
+ }
+ return pid;
+#else /* mingw32 */
+ barf("forkProcess#: primop not implemented for mingw32, sorry! (%u)\n", tso->id);
+ /* pointlessly printing out the TSOs 'id' to avoid CC unused warning. */
+ return -1;
+#endif /* mingw32 */
+}
+
+/* ---------------------------------------------------------------------------
+ * deleteAllThreads(): kill all the live threads.
+ *
+ * This is used when we catch a user interrupt (^C), before performing
+ * any necessary cleanups and running finalizers.
+ *
+ * Locks: sched_mutex held.
+ * ------------------------------------------------------------------------- */
+
+void deleteAllThreads ( void )
+{
+ StgTSO* t, *next;
+ IF_DEBUG(scheduler,sched_belch("deleting all threads"));
+ for (t = all_threads; t != END_TSO_QUEUE; t = next) {
+ next = t->global_link;
+ deleteThread(t);
+ }
+ run_queue_hd = run_queue_tl = END_TSO_QUEUE;
+ blocked_queue_hd = blocked_queue_tl = END_TSO_QUEUE;
+ sleeping_queue = END_TSO_QUEUE;
+}
+
+/* startThread and insertThread are now in GranSim.c -- HWL */
+
+
+//@node Suspend and Resume, Run queue code, Main scheduling loop, Main scheduling code
+//@subsection Suspend and Resume
+
+/* ---------------------------------------------------------------------------