-/* -----------------------------------------------------------------------------
- * $Id: Schedule.c,v 1.33 1999/11/15 14:14:43 simonmar Exp $
+/* ---------------------------------------------------------------------------
*
- * (c) The GHC Team, 1998-1999
+ * (c) The GHC Team, 1998-2004
*
* Scheduler
*
- * ---------------------------------------------------------------------------*/
-
-/* Version with scheduler monitor support for SMPs.
-
- This design provides a high-level API to create and schedule threads etc.
- as documented in the SMP design document.
-
- It uses a monitor design controlled by a single mutex to exercise control
- over accesses to shared data structures, and builds on the Posix threads
- library.
-
- The majority of state is shared. In order to keep essential per-task state,
- there is a Capability structure, which contains all the information
- needed to run a thread: its STG registers, a pointer to its TSO, a
- nursery etc. During STG execution, a pointer to the capability is
- kept in a register (BaseReg).
-
- In a non-SMP build, there is one global capability, namely MainRegTable.
-
- SDM & KH, 10/99
+ * Different GHC ways use this scheduler quite differently (see comments below)
+ * Here is the global picture:
+ *
+ * WAY Name CPP flag What's it for
+ * --------------------------------------
+ * mp GUM PAR Parallel execution on a distrib. memory machine
+ * s SMP SMP Parallel execution on a shared memory machine
+ * mg GranSim GRAN Simulation of parallel execution
+ * md GUM/GdH DIST Distributed execution (based on GUM)
+ *
+ * --------------------------------------------------------------------------*/
+
+/*
+ * Version with support for distributed memory parallelism aka GUM (WAY=mp):
+
+ The main scheduling loop in GUM iterates until a finish message is received.
+ In that case a global flag @receivedFinish@ is set and this instance of
+ the RTS shuts down. See ghc/rts/parallel/HLComms.c:processMessages()
+ for the handling of incoming messages, such as PP_FINISH.
+ Note that in the parallel case we have a system manager that coordinates
+ different PEs, each of which are running one instance of the RTS.
+ See ghc/rts/parallel/SysMan.c for the main routine of the parallel program.
+ From this routine processes executing ghc/rts/Main.c are spawned. -- HWL
+
+ * Version with support for simulating parallel execution aka GranSim (WAY=mg):
+
+ The main scheduling code in GranSim is quite different from that in std
+ (concurrent) Haskell: while concurrent Haskell just iterates over the
+ threads in the runnable queue, GranSim is event driven, i.e. it iterates
+ over the events in the global event queue. -- HWL
*/
+#include "PosixSource.h"
#include "Rts.h"
#include "SchedAPI.h"
#include "RtsUtils.h"
#include "RtsFlags.h"
+#include "BlockAlloc.h"
#include "Storage.h"
#include "StgRun.h"
-#include "StgStartup.h"
-#include "GC.h"
#include "Hooks.h"
+#define COMPILING_SCHEDULER
#include "Schedule.h"
#include "StgMiscClosures.h"
#include "Storage.h"
-#include "Evaluator.h"
+#include "Interpreter.h"
+#include "Exception.h"
#include "Printer.h"
-#include "Main.h"
#include "Signals.h"
-#include "Profiling.h"
#include "Sanity.h"
#include "Stats.h"
+#include "Timer.h"
+#include "Prelude.h"
+#include "ThreadLabels.h"
+#include "LdvProfile.h"
+#include "Updates.h"
+#ifdef PROFILING
+#include "Proftimer.h"
+#include "ProfHeap.h"
+#endif
+#if defined(GRAN) || defined(PAR)
+# include "GranSimRts.h"
+# include "GranSim.h"
+# include "ParallelRts.h"
+# include "Parallel.h"
+# include "ParallelDebug.h"
+# include "FetchMe.h"
+# include "HLC.h"
+#endif
+#include "Sparks.h"
+#include "Capability.h"
+#include "OSThreads.h"
+#include "Task.h"
-/* Main threads:
- *
- * These are the threads which clients have requested that we run.
- *
- * In an SMP build, we might have several concurrent clients all
- * waiting for results, and each one will wait on a condition variable
- * until the result is available.
- *
- * In non-SMP, clients are strictly nested: the first client calls
- * into the RTS, which might call out again to C with a _ccall_GC, and
- * eventually re-enter the RTS.
- *
- * Main threads information is kept in a linked list:
- */
-typedef struct StgMainThread_ {
- StgTSO * tso;
- SchedulerStatus stat;
- StgClosure ** ret;
-#ifdef SMP
- pthread_cond_t wakeup;
+#ifdef HAVE_SYS_TYPES_H
+#include <sys/types.h>
+#endif
+#ifdef HAVE_UNISTD_H
+#include <unistd.h>
+#endif
+
+#include <string.h>
+#include <stdlib.h>
+#include <stdarg.h>
+
+#ifdef HAVE_ERRNO_H
+#include <errno.h>
+#endif
+
+#ifdef THREADED_RTS
+#define USED_IN_THREADED_RTS
+#else
+#define USED_IN_THREADED_RTS STG_UNUSED
+#endif
+
+#ifdef RTS_SUPPORTS_THREADS
+#define USED_WHEN_RTS_SUPPORTS_THREADS
+#else
+#define USED_WHEN_RTS_SUPPORTS_THREADS STG_UNUSED
#endif
- struct StgMainThread_ *link;
-} StgMainThread;
/* Main thread queue.
* Locks required: sched_mutex.
*/
-static StgMainThread *main_threads;
+StgMainThread *main_threads = NULL;
/* Thread queues.
* Locks required: sched_mutex.
*/
-StgTSO *run_queue_hd, *run_queue_tl;
-StgTSO *blocked_queue_hd, *blocked_queue_tl;
+#if defined(GRAN)
-/* Threads suspended in _ccall_GC.
- * Locks required: sched_mutex.
+StgTSO* ActiveTSO = NULL; /* for assigning system costs; GranSim-Light only */
+/* rtsTime TimeOfNextEvent, EndOfTimeSlice; now in GranSim.c */
+
+/*
+ In GranSim we have a runnable and a blocked queue for each processor.
+ In order to minimise code changes new arrays run_queue_hds/tls
+ are created. run_queue_hd is then a short cut (macro) for
+ run_queue_hds[CurrentProc] (see GranSim.h).
+ -- HWL
+*/
+StgTSO *run_queue_hds[MAX_PROC], *run_queue_tls[MAX_PROC];
+StgTSO *blocked_queue_hds[MAX_PROC], *blocked_queue_tls[MAX_PROC];
+StgTSO *ccalling_threadss[MAX_PROC];
+/* We use the same global list of threads (all_threads) in GranSim as in
+ the std RTS (i.e. we are cheating). However, we don't use this list in
+ the GranSim specific code at the moment (so we are only potentially
+ cheating). */
+
+#else /* !GRAN */
+
+StgTSO *run_queue_hd = NULL;
+StgTSO *run_queue_tl = NULL;
+StgTSO *blocked_queue_hd = NULL;
+StgTSO *blocked_queue_tl = NULL;
+StgTSO *sleeping_queue = NULL; /* perhaps replace with a hash table? */
+
+#endif
+
+/* Linked list of all threads.
+ * Used for detecting garbage collected threads.
+ */
+StgTSO *all_threads = NULL;
+
+/* When a thread performs a safe C call (_ccall_GC, using old
+ * terminology), it gets put on the suspended_ccalling_threads
+ * list. Used by the garbage collector.
*/
static StgTSO *suspended_ccalling_threads;
-static void GetRoots(void);
static StgTSO *threadStackOverflow(StgTSO *tso);
/* KH: The following two flags are shared memory locations. There is no need
*/
/* flag set by signal handler to precipitate a context switch */
-nat context_switch;
+nat context_switch = 0;
+
/* if this flag is set as well, give up execution */
-static nat interrupted;
+rtsBool interrupted = rtsFalse;
/* Next thread ID to allocate.
- * Locks required: sched_mutex
+ * Locks required: thread_id_mutex
*/
-StgThreadID next_thread_id = 1;
+static StgThreadID next_thread_id = 1;
/*
* Pointers to the state of the current thread.
/* The smallest stack size that makes any sense is:
* RESERVED_STACK_WORDS (so we can get back from the stack overflow)
* + sizeofW(StgStopFrame) (the stg_stop_thread_info frame)
- * + 1 (the realworld token for an IO thread)
* + 1 (the closure to enter)
+ * + 1 (stg_ap_v_ret)
+ * + 1 (spare slot req'd by stg_ap_v_ret)
*
* A thread with this stack will bomb immediately with a stack
* overflow, which will increase its stack size.
*/
-#define MIN_STACK_WORDS (RESERVED_STACK_WORDS + sizeofW(StgStopFrame) + 2)
+#define MIN_STACK_WORDS (RESERVED_STACK_WORDS + sizeofW(StgStopFrame) + 3)
-/* Free capability list.
- * Locks required: sched_mutex.
- */
-#ifdef SMP
-Capability *free_capabilities; /* Available capabilities for running threads */
-nat n_free_capabilities; /* total number of available capabilities */
-#else
-Capability MainRegTable; /* for non-SMP, we have one global capability */
+
+#if defined(GRAN)
+StgTSO *CurrentTSO;
#endif
-rtsBool ready_to_gc;
+/* This is used in `TSO.h' and gcc 2.96 insists that this variable actually
+ * exists - earlier gccs apparently didn't.
+ * -= chak
+ */
+StgTSO dummy_tso;
+
+static rtsBool ready_to_gc;
-/* All our current task ids, saved in case we need to kill them later.
+/*
+ * Set to TRUE when entering a shutdown state (via shutdownHaskellAndExit()) --
+ * in an MT setting, needed to signal that a worker thread shouldn't hang around
+ * in the scheduler when it is out of work.
*/
-#ifdef SMP
-task_info *task_ids;
-#endif
+static rtsBool shutting_down_scheduler = rtsFalse;
void addToBlockedQueue ( StgTSO *tso );
-static void schedule ( void );
-static void initThread ( StgTSO *tso, nat stack_size );
+static void schedule ( StgMainThread *mainThread, Capability *initialCapability );
void interruptStgRts ( void );
-#ifdef SMP
-pthread_mutex_t sched_mutex = PTHREAD_MUTEX_INITIALIZER;
-pthread_mutex_t term_mutex = PTHREAD_MUTEX_INITIALIZER;
-pthread_cond_t thread_ready_cond = PTHREAD_COND_INITIALIZER;
-pthread_cond_t gc_pending_cond = PTHREAD_COND_INITIALIZER;
+static void detectBlackHoles ( void );
-nat await_death;
+#if defined(RTS_SUPPORTS_THREADS)
+/* ToDo: carefully document the invariants that go together
+ * with these synchronisation objects.
+ */
+Mutex sched_mutex = INIT_MUTEX_VAR;
+Mutex term_mutex = INIT_MUTEX_VAR;
+
+#endif /* RTS_SUPPORTS_THREADS */
+
+#if defined(PAR)
+StgTSO *LastTSO;
+rtsTime TimeOfLastYield;
+rtsBool emitSchedule = rtsTrue;
#endif
-/* -----------------------------------------------------------------------------
+#if DEBUG
+static char *whatNext_strs[] = {
+ "(unknown)",
+ "ThreadRunGHC",
+ "ThreadInterpret",
+ "ThreadKilled",
+ "ThreadRelocated",
+ "ThreadComplete"
+};
+#endif
+
+#if defined(PAR)
+StgTSO * createSparkThread(rtsSpark spark);
+StgTSO * activateSpark (rtsSpark spark);
+#endif
+
+/* ----------------------------------------------------------------------------
+ * Starting Tasks
+ * ------------------------------------------------------------------------- */
+
+#if defined(RTS_SUPPORTS_THREADS)
+static rtsBool startingWorkerThread = rtsFalse;
+
+static void taskStart(void);
+static void
+taskStart(void)
+{
+ ACQUIRE_LOCK(&sched_mutex);
+ startingWorkerThread = rtsFalse;
+ schedule(NULL,NULL);
+ RELEASE_LOCK(&sched_mutex);
+}
+
+void
+startSchedulerTaskIfNecessary(void)
+{
+ if(run_queue_hd != END_TSO_QUEUE
+ || blocked_queue_hd != END_TSO_QUEUE
+ || sleeping_queue != END_TSO_QUEUE)
+ {
+ if(!startingWorkerThread)
+ { // we don't want to start another worker thread
+ // just because the last one hasn't yet reached the
+ // "waiting for capability" state
+ startingWorkerThread = rtsTrue;
+ if(!startTask(taskStart))
+ {
+ startingWorkerThread = rtsFalse;
+ }
+ }
+ }
+}
+#endif
+
+/* ---------------------------------------------------------------------------
Main scheduling loop.
We use round-robin scheduling, each thread returning to the
* waiting for work, or
* waiting for a GC to complete.
- -------------------------------------------------------------------------- */
-
+ GRAN version:
+ In a GranSim setup this loop iterates over the global event queue.
+ This revolves around the global event queue, which determines what
+ to do next. Therefore, it's more complicated than either the
+ concurrent or the parallel (GUM) setup.
+
+ GUM version:
+ GUM iterates over incoming messages.
+ It starts with nothing to do (thus CurrentTSO == END_TSO_QUEUE),
+ and sends out a fish whenever it has nothing to do; in-between
+ doing the actual reductions (shared code below) it processes the
+ incoming messages and deals with delayed operations
+ (see PendingFetches).
+ This is not the ugliest code you could imagine, but it's bloody close.
+
+ ------------------------------------------------------------------------ */
static void
-schedule( void )
+schedule( StgMainThread *mainThread USED_WHEN_RTS_SUPPORTS_THREADS,
+ Capability *initialCapability )
{
StgTSO *t;
Capability *cap;
StgThreadReturnCode ret;
+#if defined(GRAN)
+ rtsEvent *event;
+#elif defined(PAR)
+ StgSparkPool *pool;
+ rtsSpark spark;
+ StgTSO *tso;
+ GlobalTaskId pe;
+ rtsBool receivedFinish = rtsFalse;
+# if defined(DEBUG)
+ nat tp_size, sp_size; // stats only
+# endif
+#endif
+ rtsBool was_interrupted = rtsFalse;
+ nat prev_what_next;
- ACQUIRE_LOCK(&sched_mutex);
+ // Pre-condition: sched_mutex is held.
+ // We might have a capability, passed in as initialCapability.
+ cap = initialCapability;
+
+#if defined(RTS_SUPPORTS_THREADS)
+ //
+ // in the threaded case, the capability is either passed in via the
+ // initialCapability parameter, or initialized inside the scheduler
+ // loop
+ //
+ IF_DEBUG(scheduler,
+ sched_belch("### NEW SCHEDULER LOOP (main thr: %p, cap: %p)",
+ mainThread, initialCapability);
+ );
+#else
+ // simply initialise it in the non-threaded case
+ grabCapability(&cap);
+#endif
+
+#if defined(GRAN)
+ /* set up first event to get things going */
+ /* ToDo: assign costs for system setup and init MainTSO ! */
+ new_event(CurrentProc, CurrentProc, CurrentTime[CurrentProc],
+ ContinueThread,
+ CurrentTSO, (StgClosure*)NULL, (rtsSpark*)NULL);
+
+ IF_DEBUG(gran,
+ fprintf(stderr, "GRAN: Init CurrentTSO (in schedule) = %p\n", CurrentTSO);
+ G_TSO(CurrentTSO, 5));
+
+ if (RtsFlags.GranFlags.Light) {
+ /* Save current time; GranSim Light only */
+ CurrentTSO->gran.clock = CurrentTime[CurrentProc];
+ }
+
+ event = get_next_event();
+
+ while (event!=(rtsEvent*)NULL) {
+ /* Choose the processor with the next event */
+ CurrentProc = event->proc;
+ CurrentTSO = event->tso;
+
+#elif defined(PAR)
+
+ while (!receivedFinish) { /* set by processMessages */
+ /* when receiving PP_FINISH message */
+
+#else // everything except GRAN and PAR
while (1) {
- /* If we're interrupted (the user pressed ^C, or some other
- * termination condition occurred), kill all the currently running
- * threads.
- */
- if (interrupted) {
- IF_DEBUG(scheduler,belch("schedule: interrupted"));
- for (t = run_queue_hd; t != END_TSO_QUEUE; t = t->link) {
- deleteThread(t);
+#endif
+
+ IF_DEBUG(scheduler, printAllThreads());
+
+#if defined(RTS_SUPPORTS_THREADS)
+ // Yield the capability to higher-priority tasks if necessary.
+ //
+ if (cap != NULL) {
+ yieldCapability(&cap);
}
- for (t = blocked_queue_hd; t != END_TSO_QUEUE; t = t->link) {
- deleteThread(t);
+
+ // If we do not currently hold a capability, we wait for one
+ //
+ if (cap == NULL) {
+ waitForCapability(&sched_mutex, &cap,
+ mainThread ? &mainThread->bound_thread_cond : NULL);
}
- run_queue_hd = run_queue_tl = END_TSO_QUEUE;
- blocked_queue_hd = blocked_queue_tl = END_TSO_QUEUE;
+
+ // We now have a capability...
+#endif
+
+ //
+ // If we're interrupted (the user pressed ^C, or some other
+ // termination condition occurred), kill all the currently running
+ // threads.
+ //
+ if (interrupted) {
+ IF_DEBUG(scheduler, sched_belch("interrupted"));
+ interrupted = rtsFalse;
+ was_interrupted = rtsTrue;
+#if defined(RTS_SUPPORTS_THREADS)
+ // In the threaded RTS, deadlock detection doesn't work,
+ // so just exit right away.
+ prog_belch("interrupted");
+ releaseCapability(cap);
+ RELEASE_LOCK(&sched_mutex);
+ shutdownHaskellAndExit(EXIT_SUCCESS);
+#else
+ deleteAllThreads();
+#endif
}
- /* Go through the list of main threads and wake up any
- * clients whose computations have finished. ToDo: this
- * should be done more efficiently without a linear scan
- * of the main threads list, somehow...
- */
-#ifdef SMP
- {
- StgMainThread *m, **prev;
- prev = &main_threads;
- for (m = main_threads; m != NULL; m = m->link) {
- if (m->tso->whatNext == ThreadComplete) {
- if (m->ret) {
- *(m->ret) = (StgClosure *)m->tso->sp[0];
- }
- *prev = m->link;
- m->stat = Success;
- pthread_cond_broadcast(&m->wakeup);
- }
- if (m->tso->whatNext == ThreadKilled) {
- *prev = m->link;
- m->stat = Killed;
- pthread_cond_broadcast(&m->wakeup);
- }
- }
+#if defined(RTS_USER_SIGNALS)
+ // check for signals each time around the scheduler
+ if (signals_pending()) {
+ RELEASE_LOCK(&sched_mutex); /* ToDo: kill */
+ startSignalHandlers();
+ ACQUIRE_LOCK(&sched_mutex);
}
-#else
- /* If our main thread has finished or been killed, return.
+#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.
+ //
+ if ( !EMPTY_QUEUE(blocked_queue_hd) || !EMPTY_QUEUE(sleeping_queue)
+#if defined(RTS_SUPPORTS_THREADS)
+ || EMPTY_RUN_QUEUE()
+#endif
+ )
+ {
+ awaitEvent( EMPTY_RUN_QUEUE() );
+ }
+ // 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.
*/
+#if !defined(PAR) && !defined(RTS_SUPPORTS_THREADS)
+ if ( EMPTY_THREAD_QUEUES() )
{
- StgMainThread *m = main_threads;
- if (m->tso->whatNext == ThreadComplete
- || m->tso->whatNext == ThreadKilled) {
- main_threads = main_threads->link;
- if (m->tso->whatNext == ThreadComplete) {
- /* we finished successfully, fill in the return value */
- if (m->ret) { *(m->ret) = (StgClosure *)m->tso->sp[0]; };
- m->stat = Success;
- return;
- } else {
- m->stat = Killed;
- return;
+ IF_DEBUG(scheduler, sched_belch("deadlocked, forcing major GC..."));
+ // 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; }
+
+#if defined(RTS_USER_SIGNALS)
+ /* If we have user-installed signal handlers, then wait
+ * for signals to arrive rather then bombing out with a
+ * deadlock.
+ */
+ if ( anyUserHandlers() ) {
+ 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
- /* 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 (blocked_queue_hd != END_TSO_QUEUE) {
- awaitEvent(
- (run_queue_hd == END_TSO_QUEUE)
-#ifdef SMP
- && (n_free_capabilities == RtsFlags.ConcFlags.nNodes)
-#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;
+ m = main_threads;
+ switch (m->tso->why_blocked) {
+ case BlockedOnBlackHole:
+ case BlockedOnException:
+ case BlockedOnMVar:
+ raiseAsync(m->tso, (StgClosure *)NonTermination_closure);
+ break;
+ default:
+ barf("deadlock: main thread blocked in a strange way");
+ }
+ }
}
-
- /* check for signals each time around the scheduler */
-#ifndef __MINGW32__
- if (signals_pending()) {
- start_signal_handlers();
+ not_deadlocked:
+
+#elif defined(RTS_SUPPORTS_THREADS)
+ // ToDo: add deadlock detection in threaded RTS
+#elif defined(PAR)
+ // ToDo: add deadlock detection in GUM (similar to SMP) -- HWL
+#endif
+
+#if defined(RTS_SUPPORTS_THREADS)
+ if ( EMPTY_RUN_QUEUE() ) {
+ continue; // nothing to do
}
#endif
- /* 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. Inform
- * all the main threads.
- */
-#ifdef SMP
- if (blocked_queue_hd == END_TSO_QUEUE
- && run_queue_hd == END_TSO_QUEUE
- && (n_free_capabilities == RtsFlags.ConcFlags.nNodes)
- ) {
- StgMainThread *m;
- for (m = main_threads; m != NULL; m = m->link) {
- m->ret = NULL;
- m->stat = Deadlock;
- pthread_cond_broadcast(&m->wakeup);
+#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
}
- main_threads = NULL;
+ /*
+ 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. */
+ POP_RUN_QUEUE(t); // 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();
}
-#else /* ! SMP */
- if (blocked_queue_hd == END_TSO_QUEUE
- && run_queue_hd == END_TSO_QUEUE) {
- StgMainThread *m = main_threads;
- m->ret = NULL;
- m->stat = Deadlock;
- main_threads = m->link;
- return;
+
+ /* 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();
}
-#endif
-#ifdef SMP
- /* If there's a GC pending, don't do anything until it has
- * completed.
- */
- if (ready_to_gc) {
- IF_DEBUG(scheduler,fprintf(stderr,"schedule (task %ld): waiting for GC\n",
- pthread_self()););
- pthread_cond_wait(&gc_pending_cond, &sched_mutex);
+ /* 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 */
+ POP_RUN_QUEUE(t); // 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);
}
-
- /* block until we've got a thread on the run queue and a free
- * capability.
- */
- while (run_queue_hd == END_TSO_QUEUE || free_capabilities == NULL) {
- IF_DEBUG(scheduler,
- fprintf(stderr, "schedule (task %ld): waiting for work\n",
- pthread_self()););
- pthread_cond_wait(&thread_ready_cond, &sched_mutex);
- IF_DEBUG(scheduler,
- fprintf(stderr, "schedule (task %ld): work now available\n",
- pthread_self()););
+
+ 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
+
+# endif
+#else /* !GRAN && !PAR */
- /* grab a thread from the run queue
- */
- t = POP_RUN_QUEUE();
-
- /* grab a capability
- */
-#ifdef SMP
- cap = free_capabilities;
- free_capabilities = cap->link;
- n_free_capabilities--;
-#else
- cap = &MainRegTable;
+ // grab a thread from the run queue
+ ASSERT(run_queue_hd != END_TSO_QUEUE);
+ POP_RUN_QUEUE(t);
+
+ // 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
+
+#ifdef THREADED_RTS
+ {
+ StgMainThread *m = t->main;
+
+ if(m)
+ {
+ if(m == mainThread)
+ {
+ IF_DEBUG(scheduler,
+ sched_belch("### Running thread %d in bound thread", t->id));
+ // yes, the Haskell thread is bound to the current native thread
+ }
+ else
+ {
+ IF_DEBUG(scheduler,
+ sched_belch("### thread %d bound to another OS thread", t->id));
+ // no, bound to a different Haskell thread: pass to that thread
+ PUSH_ON_RUN_QUEUE(t);
+ passCapability(&m->bound_thread_cond);
+ continue;
+ }
+ }
+ else
+ {
+ if(mainThread != NULL)
+ // The thread we want to run is bound.
+ {
+ IF_DEBUG(scheduler,
+ sched_belch("### this OS thread cannot run thread %d", t->id));
+ // no, the current native thread is bound to a different
+ // Haskell thread, so pass it to any worker thread
+ PUSH_ON_RUN_QUEUE(t);
+ passCapabilityToWorker();
+ continue;
+ }
+ }
+ }
+#endif
+
+ cap->r.rCurrentTSO = t;
- cap->rCurrentTSO = t;
-
- /* set the context_switch flag
+ /* context switches are now initiated by the timer signal, unless
+ * the user specified "context switch as often as possible", with
+ * +RTS -C0
*/
- if (run_queue_hd == END_TSO_QUEUE)
- context_switch = 0;
- else
- context_switch = 1;
+ if ((RtsFlags.ConcFlags.ctxtSwitchTicks == 0
+ && (run_queue_hd != END_TSO_QUEUE
+ || blocked_queue_hd != END_TSO_QUEUE
+ || sleeping_queue != END_TSO_QUEUE)))
+ context_switch = 1;
+
+run_thread:
RELEASE_LOCK(&sched_mutex);
-
-#ifdef SMP
- IF_DEBUG(scheduler,fprintf(stderr,"schedule (task %ld): running thread %d\n", pthread_self(),t->id));
-#else
- IF_DEBUG(scheduler,fprintf(stderr,"schedule: running thread %d\n",t->id));
+
+ IF_DEBUG(scheduler, sched_belch("-->> running thread %ld %s ...",
+ t->id, whatNext_strs[t->what_next]));
+
+#ifdef PROFILING
+ startHeapProfTimer();
#endif
+ /* +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ */
/* Run the current thread
*/
- switch (cap->rCurrentTSO->whatNext) {
+ prev_what_next = t->what_next;
+
+ errno = t->saved_errno;
+
+ switch (prev_what_next) {
+
case ThreadKilled:
case ThreadComplete:
- /* Thread already finished, return to scheduler. */
- ret = ThreadFinished;
- break;
- case ThreadEnterGHC:
- ret = StgRun((StgFunPtr) stg_enterStackTop, cap);
- break;
+ /* Thread already finished, return to scheduler. */
+ ret = ThreadFinished;
+ break;
+
case ThreadRunGHC:
- ret = StgRun((StgFunPtr) stg_returnToStackTop, cap);
- break;
- case ThreadEnterHugs:
-#ifdef INTERPRETER
- {
- StgClosure* c;
- IF_DEBUG(scheduler,belch("schedule: entering Hugs"));
- c = (StgClosure *)(cap->rCurrentTSO->sp[0]);
- cap->rCurrentTSO->sp += 1;
- ret = enter(cap,c);
- break;
- }
-#else
- barf("Panic: entered a BCO but no bytecode interpreter in this build");
-#endif
+ ret = StgRun((StgFunPtr) stg_returnToStackTop, &cap->r);
+ break;
+
+ case ThreadInterpret:
+ ret = interpretBCO(cap);
+ break;
+
default:
- barf("schedule: invalid whatNext field");
+ barf("schedule: invalid what_next field");
}
+
+ // The TSO might have moved, so find the new location:
+ t = cap->r.rCurrentTSO;
+
+ // And save the current errno in this thread.
+ t->saved_errno = errno;
+
+ /* +++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++++ */
/* 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,"schedule (task %ld): ", pthread_self()););
-#else
- IF_DEBUG(scheduler,fprintf(stderr,"schedule: "););
+
+#ifdef RTS_SUPPORTS_THREADS
+ IF_DEBUG(scheduler,fprintf(stderr,"sched (task %p): ", osThreadId()););
+#elif !defined(GRAN) && !defined(PAR)
+ IF_DEBUG(scheduler,fprintf(stderr,"sched: "););
#endif
- t = cap->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) {
+ // 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) / BLOCK_SIZE;
+
+ IF_DEBUG(scheduler,belch("--<< thread %ld (%s) stopped: requesting a large block (size %d)",
+ t->id, 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;
+ }
+ }
+
+ // don't forget to update the block count in g0s0.
+ g0s0->n_blocks += blocks;
+ // This assert can be a killer if the app is doing lots
+ // of large block allocations.
+ 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 stopped: HeapOverflow", t->id));
+ IF_DEBUG(scheduler,belch("--<< thread %ld (%s) stopped: HeapOverflow",
+ t->id, 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 (%s) stopped, StackOverflow",
+ t->id, whatNext_strs[t->what_next]));
/* just adjust the stack for this thread, then pop it back
* on the run queue.
*/
- IF_DEBUG(scheduler,belch("thread %ld stopped, StackOverflow", t->id));
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)
+ * (it shouldn't be).
*/
- for (m = main_threads; m != NULL; m = m->link) {
- if (m->tso == t) {
- m->tso = new_t;
- }
+ if (t->main != NULL) {
+ t->main->tso = new_t;
}
PUSH_ON_RUN_QUEUE(new_t);
}
break;
case ThreadYielding:
+ // Reset the context switch flag. We don't do this just before
+ // running the thread, because that would mean we would lose ticks
+ // during GC, which can lead to unfair scheduling (a thread hogs
+ // the CPU because the tick always arrives during GC). This way
+ // penalises threads that do a lot of allocation, but that seems
+ // better than the alternative.
+ context_switch = 0;
+
+#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->whatNext == ThreadEnterHugs) {
- /* ToDo: or maybe a timer expired when we were in Hugs?
- * or maybe someone hit ctrl-C
- */
- belch("thread %ld stopped to switch to Hugs", t->id);
- } else {
- belch("thread %ld stopped, yielding", t->id);
- }
- );
+ if (t->what_next != prev_what_next) {
+ belch("--<< thread %ld (%s) stopped to switch evaluators",
+ t->id, whatNext_strs[t->what_next]);
+ } else {
+ belch("--<< thread %ld (%s) stopped, yielding",
+ t->id, whatNext_strs[t->what_next]);
+ }
+ );
+
+ IF_DEBUG(sanity,
+ //belch("&& Doing sanity check on yielding TSO %ld.", t->id);
+ checkTSO(t));
+ ASSERT(t->link == END_TSO_QUEUE);
+
+ // Shortcut if we're just switching evaluators: don't bother
+ // doing stack squeezing (which can be expensive), just run the
+ // thread.
+ if (t->what_next != prev_what_next) {
+ goto run_thread;
+ }
+
threadPaused(t);
+
+#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 stopped, ", t->id);
+ fprintf(stderr, "--<< thread %d (%s) stopped: ",
+ t->id, whatNext_strs[t->what_next]);
printThreadBlockage(t);
fprintf(stderr, "\n"));
+ fflush(stderr);
+
+ /* 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.
*/
- IF_DEBUG(scheduler,belch("thread %ld finished", t->id));
- t->whatNext = ThreadComplete;
- break;
+ /* We also end up here if the thread kills itself with an
+ * uncaught exception, see Exception.hc.
+ */
+ IF_DEBUG(scheduler,belch("--++ thread %d (%s) finished",
+ t->id, whatNext_strs[t->what_next]));
+#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
+
+ //
+ // Check whether the thread that just completed was a main
+ // thread, and if so return with the result.
+ //
+ // There is an assumption here that all thread completion goes
+ // through this point; we need to make sure that if a thread
+ // ends up in the ThreadKilled state, that it stays on the run
+ // queue so it can be dealt with here.
+ //
+ if (
+#if defined(RTS_SUPPORTS_THREADS)
+ mainThread != NULL
+#else
+ mainThread->tso == t
+#endif
+ )
+ {
+ // We are a bound thread: this must be our thread that just
+ // completed.
+ ASSERT(mainThread->tso == t);
+
+ if (t->what_next == ThreadComplete) {
+ if (mainThread->ret) {
+ // NOTE: return val is tso->sp[1] (see StgStartup.hc)
+ *(mainThread->ret) = (StgClosure *)mainThread->tso->sp[1];
+ }
+ mainThread->stat = Success;
+ } else {
+ if (mainThread->ret) {
+ *(mainThread->ret) = NULL;
+ }
+ if (was_interrupted) {
+ mainThread->stat = Interrupted;
+ } else {
+ mainThread->stat = Killed;
+ }
+ }
+#ifdef DEBUG
+ removeThreadLabel((StgWord)mainThread->tso->id);
+#endif
+ if (mainThread->prev == NULL) {
+ main_threads = mainThread->link;
+ } else {
+ mainThread->prev->link = mainThread->link;
+ }
+ if (mainThread->link != NULL) {
+ mainThread->link->prev = NULL;
+ }
+ releaseCapability(cap);
+ return;
+ }
+
+#ifdef RTS_SUPPORTS_THREADS
+ ASSERT(t->main == NULL);
+#else
+ if (t->main != NULL) {
+ // Must be a main thread that is not the topmost one. Leave
+ // it on the run queue until the stack has unwound to the
+ // point where we can deal with this. Leaving it on the run
+ // queue also ensures that the garbage collector knows about
+ // this thread and its return value (it gets dropped from the
+ // all_threads list so there's no other way to find it).
+ APPEND_TO_RUN_QUEUE(t);
+ }
+#endif
+ break;
+
default:
- barf("doneThread: invalid thread return code");
+ barf("schedule: invalid thread return code %d", (int)ret);
+ }
+
+#ifdef PROFILING
+ // When we have +RTS -i0 and we're heap profiling, do a census at
+ // every GC. This lets us get repeatable runs for debugging.
+ if (performHeapProfile ||
+ (RtsFlags.ProfFlags.profileInterval==0 &&
+ RtsFlags.ProfFlags.doHeapProfile && ready_to_gc)) {
+ GarbageCollect(GetRoots, rtsTrue);
+ heapCensus();
+ performHeapProfile = rtsFalse;
+ ready_to_gc = rtsFalse; // we already GC'd
}
-
-#ifdef SMP
- cap->link = free_capabilities;
- free_capabilities = cap;
- n_free_capabilities++;
#endif
-#ifdef SMP
- if (ready_to_gc && n_free_capabilities == RtsFlags.ConcFlags.nNodes) {
-#else
if (ready_to_gc) {
-#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.
*/
-#ifdef SMP
- IF_DEBUG(scheduler,belch("schedule (task %ld): doing GC", pthread_self()));
+#if defined(RTS_SUPPORTS_THREADS)
+ IF_DEBUG(scheduler,sched_belch("doing GC"));
#endif
- GarbageCollect(GetRoots);
+ GarbageCollect(GetRoots,rtsFalse);
ready_to_gc = rtsFalse;
-#ifdef SMP
- pthread_cond_broadcast(&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"));
}
-/* -----------------------------------------------------------------------------
+/* ---------------------------------------------------------------------------
+ * rtsSupportsBoundThreads(): is the RTS built to support bound threads?
+ * used by Control.Concurrent for error checking.
+ * ------------------------------------------------------------------------- */
+
+StgBool
+rtsSupportsBoundThreads(void)
+{
+#ifdef THREADED_RTS
+ return rtsTrue;
+#else
+ return rtsFalse;
+#endif
+}
+
+/* ---------------------------------------------------------------------------
+ * isThreadBound(tso): check whether tso is bound to an OS thread.
+ * ------------------------------------------------------------------------- */
+
+StgBool
+isThreadBound(StgTSO* tso USED_IN_THREADED_RTS)
+{
+#ifdef THREADED_RTS
+ return (tso->main != NULL);
+#endif
+ return rtsFalse;
+}
+
+/* ---------------------------------------------------------------------------
+ * Singleton fork(). Do not copy any running threads.
+ * ------------------------------------------------------------------------- */
+
+#ifndef mingw32_TARGET_OS
+#define FORKPROCESS_PRIMOP_SUPPORTED
+#endif
+
+#ifdef FORKPROCESS_PRIMOP_SUPPORTED
+static void
+deleteThreadImmediately(StgTSO *tso);
+#endif
+StgInt
+forkProcess(HsStablePtr *entry
+#ifndef FORKPROCESS_PRIMOP_SUPPORTED
+ STG_UNUSED
+#endif
+ )
+{
+#ifdef FORKPROCESS_PRIMOP_SUPPORTED
+ pid_t pid;
+ StgTSO* t,*next;
+ StgMainThread *m;
+ SchedulerStatus rc;
+
+ IF_DEBUG(scheduler,sched_belch("forking!"));
+ rts_lock(); // This not only acquires sched_mutex, it also
+ // makes sure that no other threads are running
+
+ pid = fork();
+
+ if (pid) { /* parent */
+
+ /* just return the pid */
+ rts_unlock();
+ return pid;
+
+ } else { /* child */
+
+
+ // delete all threads
+ run_queue_hd = run_queue_tl = END_TSO_QUEUE;
+
+ for (t = all_threads; t != END_TSO_QUEUE; t = next) {
+ next = t->link;
+
+ // don't allow threads to catch the ThreadKilled exception
+ deleteThreadImmediately(t);
+ }
+
+ // wipe the main thread list
+ while((m = main_threads) != NULL) {
+ main_threads = m->link;
+# ifdef THREADED_RTS
+ closeCondition(&m->bound_thread_cond);
+# endif
+ stgFree(m);
+ }
+
+# ifdef RTS_SUPPORTS_THREADS
+ resetTaskManagerAfterFork(); // tell startTask() and friends that
+ startingWorkerThread = rtsFalse; // we have no worker threads any more
+ resetWorkerWakeupPipeAfterFork();
+# endif
+
+ rc = rts_evalStableIO(entry, NULL); // run the action
+ rts_checkSchedStatus("forkProcess",rc);
+
+ rts_unlock();
+
+ hs_exit(); // clean up and exit
+ stg_exit(0);
+ }
+#else /* !FORKPROCESS_PRIMOP_SUPPORTED */
+ barf("forkProcess#: primop not supported, sorry!\n");
+ return -1;
+#endif
+}
+
+/* ---------------------------------------------------------------------------
+ * 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);
+ }
+
+ // The run queue now contains a bunch of ThreadKilled threads. We
+ // must not throw these away: the main thread(s) will be in there
+ // somewhere, and the main scheduler loop has to deal with it.
+ // Also, the run queue is the only thing keeping these threads from
+ // being GC'd, and we don't want the "main thread has been GC'd" panic.
+
+ ASSERT(blocked_queue_hd == END_TSO_QUEUE);
+ ASSERT(sleeping_queue == END_TSO_QUEUE);
+}
+
+/* startThread and insertThread are now in GranSim.c -- HWL */
+
+
+/* ---------------------------------------------------------------------------
* Suspending & resuming Haskell threads.
*
* When making a "safe" call to C (aka _ccall_GC), the task gives back
* duration of the call, on the susepended_ccalling_threads queue. We
* give out a token to the task, which it can use to resume the thread
* on return from the C function.
- * -------------------------------------------------------------------------- */
+ * ------------------------------------------------------------------------- */
StgInt
-suspendThread( Capability *cap )
+suspendThread( StgRegTable *reg )
{
nat tok;
+ Capability *cap;
+ int saved_errno = errno;
+
+ /* assume that *reg is a pointer to the StgRegTable part
+ * of a Capability.
+ */
+ cap = (Capability *)((void *)((unsigned char*)reg - sizeof(StgFunTable)));
ACQUIRE_LOCK(&sched_mutex);
-#ifdef SMP
- IF_DEBUG(scheduler,
- fprintf(stderr, "schedule (task %ld): thread %d did a _ccall_gc\n",
- pthread_self(), cap->rCurrentTSO->id));
-#else
IF_DEBUG(scheduler,
- fprintf(stderr, "schedule: thread %d did a _ccall_gc\n",
- cap->rCurrentTSO->id));
-#endif
+ sched_belch("thread %d did a _ccall_gc", cap->r.rCurrentTSO->id));
+
+ // XXX this might not be necessary --SDM
+ cap->r.rCurrentTSO->what_next = ThreadRunGHC;
- threadPaused(cap->rCurrentTSO);
- cap->rCurrentTSO->link = suspended_ccalling_threads;
- suspended_ccalling_threads = cap->rCurrentTSO;
+ threadPaused(cap->r.rCurrentTSO);
+ cap->r.rCurrentTSO->link = suspended_ccalling_threads;
+ suspended_ccalling_threads = cap->r.rCurrentTSO;
+
+ if(cap->r.rCurrentTSO->blocked_exceptions == NULL) {
+ cap->r.rCurrentTSO->why_blocked = BlockedOnCCall;
+ cap->r.rCurrentTSO->blocked_exceptions = END_TSO_QUEUE;
+ } else {
+ cap->r.rCurrentTSO->why_blocked = BlockedOnCCall_NoUnblockExc;
+ }
/* Use the thread ID as the token; it should be unique */
- tok = cap->rCurrentTSO->id;
+ tok = cap->r.rCurrentTSO->id;
-#ifdef SMP
- cap->link = free_capabilities;
- free_capabilities = cap;
- n_free_capabilities++;
+ /* Hand back capability */
+ releaseCapability(cap);
+
+#if defined(RTS_SUPPORTS_THREADS)
+ /* Preparing to leave the RTS, so ensure there's a native thread/task
+ waiting to take over.
+ */
+ IF_DEBUG(scheduler, sched_belch("worker (token %d): leaving RTS", tok));
#endif
+ /* Other threads _might_ be available for execution; signal this */
+ THREAD_RUNNABLE();
RELEASE_LOCK(&sched_mutex);
+
+ errno = saved_errno;
return tok;
}
-Capability *
+StgRegTable *
resumeThread( StgInt tok )
{
StgTSO *tso, **prev;
Capability *cap;
+ int saved_errno = errno;
+#if defined(RTS_SUPPORTS_THREADS)
+ /* Wait for permission to re-enter the RTS with the result. */
ACQUIRE_LOCK(&sched_mutex);
+ waitForReturnCapability(&sched_mutex, &cap);
+ IF_DEBUG(scheduler, sched_belch("worker (token %d): re-entering RTS", tok));
+#else
+ grabCapability(&cap);
+#endif
+
+ /* Remove the thread off of the suspended list */
prev = &suspended_ccalling_threads;
for (tso = suspended_ccalling_threads;
tso != END_TSO_QUEUE;
if (tso == END_TSO_QUEUE) {
barf("resumeThread: thread not found");
}
-
-#ifdef SMP
- while (free_capabilities == NULL) {
- IF_DEBUG(scheduler,
- fprintf(stderr,"schedule (task %ld): waiting to resume\n",
- pthread_self()));
- pthread_cond_wait(&thread_ready_cond, &sched_mutex);
- IF_DEBUG(scheduler,fprintf(stderr,
- "schedule (task %ld): resuming thread %d\n",
- pthread_self(), tso->id));
+ tso->link = END_TSO_QUEUE;
+
+ if(tso->why_blocked == BlockedOnCCall) {
+ awakenBlockedQueueNoLock(tso->blocked_exceptions);
+ tso->blocked_exceptions = NULL;
}
- cap = free_capabilities;
- free_capabilities = cap->link;
- n_free_capabilities--;
-#else
- cap = &MainRegTable;
-#endif
-
- cap->rCurrentTSO = tso;
+
+ /* Reset blocking status */
+ tso->why_blocked = NotBlocked;
+ cap->r.rCurrentTSO = tso;
RELEASE_LOCK(&sched_mutex);
- return cap;
+ errno = saved_errno;
+ return &cap->r;
}
-/* -----------------------------------------------------------------------------
+
+/* ---------------------------------------------------------------------------
* Static functions
- * -------------------------------------------------------------------------- */
+ * ------------------------------------------------------------------------ */
static void unblockThread(StgTSO *tso);
-/* -----------------------------------------------------------------------------
+/* ---------------------------------------------------------------------------
* Comparing Thread ids.
*
* This is used from STG land in the implementation of the
* instances of Eq/Ord for ThreadIds.
- * -------------------------------------------------------------------------- */
+ * ------------------------------------------------------------------------ */
-int cmp_thread(const StgTSO *tso1, const StgTSO *tso2)
+int
+cmp_thread(StgPtr tso1, StgPtr tso2)
{
- StgThreadID id1 = tso1->id;
- StgThreadID id2 = tso2->id;
+ StgThreadID id1 = ((StgTSO *)tso1)->id;
+ StgThreadID id2 = ((StgTSO *)tso2)->id;
if (id1 < id2) return (-1);
if (id1 > id2) return 1;
return 0;
}
-/* -----------------------------------------------------------------------------
+/* ---------------------------------------------------------------------------
+ * Fetching the ThreadID from an StgTSO.
+ *
+ * This is used in the implementation of Show for ThreadIds.
+ * ------------------------------------------------------------------------ */
+int
+rts_getThreadId(StgPtr tso)
+{
+ return ((StgTSO *)tso)->id;
+}
+
+#ifdef DEBUG
+void
+labelThread(StgPtr tso, char *label)
+{
+ int len;
+ void *buf;
+
+ /* Caveat: Once set, you can only set the thread name to "" */
+ len = strlen(label)+1;
+ buf = stgMallocBytes(len * sizeof(char), "Schedule.c:labelThread()");
+ strncpy(buf,label,len);
+ /* Update will free the old memory for us */
+ updateThreadLabel(((StgTSO *)tso)->id,buf);
+}
+#endif /* DEBUG */
+
+/* ---------------------------------------------------------------------------
Create a new thread.
The new thread starts with the given stack size. Before the
createGenThread() and createIOThread() (in SchedAPI.h) are
convenient packaged versions of this function.
- -------------------------------------------------------------------------- */
+ currently pri (priority) is only used in a GRAN setup -- HWL
+ ------------------------------------------------------------------------ */
+#if defined(GRAN)
+/* currently pri (priority) is only used in a GRAN setup -- HWL */
+StgTSO *
+createThread(nat size, StgInt pri)
+#else
StgTSO *
-createThread(nat stack_size)
+createThread(nat size)
+#endif
{
- StgTSO *tso;
+
+ StgTSO *tso;
+ nat stack_size;
+
+ /* First check whether we should create a thread at all */
+#if defined(PAR)
+ /* check that no more than RtsFlags.ParFlags.maxThreads threads are created */
+ if (advisory_thread_count >= RtsFlags.ParFlags.maxThreads) {
+ threadsIgnored++;
+ belch("{createThread}Daq ghuH: refusing to create another thread; no more than %d threads allowed (currently %d)",
+ RtsFlags.ParFlags.maxThreads, advisory_thread_count);
+ return END_TSO_QUEUE;
+ }
+ threadsCreated++;
+#endif
+
+#if defined(GRAN)
+ ASSERT(!RtsFlags.GranFlags.Light || CurrentProc==0);
+#endif
+
+ // ToDo: check whether size = stack_size - TSO_STRUCT_SIZEW
/* catch ridiculously small stack sizes */
- if (stack_size < MIN_STACK_WORDS + TSO_STRUCT_SIZEW) {
- stack_size = MIN_STACK_WORDS + TSO_STRUCT_SIZEW;
+ if (size < MIN_STACK_WORDS + TSO_STRUCT_SIZEW) {
+ size = MIN_STACK_WORDS + TSO_STRUCT_SIZEW;
}
- tso = (StgTSO *)allocate(stack_size);
- TICK_ALLOC_TSO(stack_size-sizeofW(StgTSO),0);
-
- initThread(tso, stack_size - TSO_STRUCT_SIZEW);
- return tso;
-}
+ stack_size = size - TSO_STRUCT_SIZEW;
-void
-initThread(StgTSO *tso, nat stack_size)
-{
- SET_INFO(tso,&TSO_info);
- tso->whatNext = ThreadEnterGHC;
-
- /* tso->id needs to be unique. For now we use a heavyweight mutex to
- protect the increment operation on next_thread_id.
- In future, we could use an atomic increment instead.
- */
-
- ACQUIRE_LOCK(&sched_mutex);
- tso->id = next_thread_id++;
- RELEASE_LOCK(&sched_mutex);
+ tso = (StgTSO *)allocate(size);
+ TICK_ALLOC_TSO(stack_size, 0);
+
+ SET_HDR(tso, &stg_TSO_info, CCS_SYSTEM);
+#if defined(GRAN)
+ SET_GRAN_HDR(tso, ThisPE);
+#endif
+ // Always start with the compiled code evaluator
+ tso->what_next = ThreadRunGHC;
+
+ tso->id = next_thread_id++;
tso->why_blocked = NotBlocked;
+ tso->blocked_exceptions = NULL;
- tso->splim = (P_)&(tso->stack) + RESERVED_STACK_WORDS;
+ tso->saved_errno = 0;
+ tso->main = NULL;
+
tso->stack_size = stack_size;
tso->max_stack_size = round_to_mblocks(RtsFlags.GcFlags.maxStkSize)
- TSO_STRUCT_SIZEW;
/* put a stop frame on the stack */
tso->sp -= sizeofW(StgStopFrame);
- SET_HDR((StgClosure*)tso->sp,(StgInfoTable *)&stg_stop_thread_info,CCS_MAIN);
- tso->su = (StgUpdateFrame*)tso->sp;
+ SET_HDR((StgClosure*)tso->sp,(StgInfoTable *)&stg_stop_thread_info,CCS_SYSTEM);
+ tso->link = END_TSO_QUEUE;
+
+ // ToDo: check this
+#if defined(GRAN)
+ /* uses more flexible routine in GranSim */
+ insertThread(tso, CurrentProc);
+#else
+ /* In a non-GranSim setup the pushing of a TSO onto the runq is separated
+ * from its creation
+ */
+#endif
- IF_DEBUG(scheduler,belch("schedule: Initialised thread %ld, stack size = %lx words",
- tso->id, tso->stack_size));
+#if defined(GRAN)
+ if (RtsFlags.GranFlags.GranSimStats.Full)
+ DumpGranEvent(GR_START,tso);
+#elif defined(PAR)
+ if (RtsFlags.ParFlags.ParStats.Full)
+ DumpGranEvent(GR_STARTQ,tso);
+ /* HACk to avoid SCHEDULE
+ LastTSO = tso; */
+#endif
+
+ /* Link the new thread on the global thread list.
+ */
+ tso->global_link = all_threads;
+ all_threads = tso;
+
+#if defined(DIST)
+ tso->dist.priority = MandatoryPriority; //by default that is...
+#endif
+
+#if defined(GRAN)
+ tso->gran.pri = pri;
+# if defined(DEBUG)
+ tso->gran.magic = TSO_MAGIC; // debugging only
+# endif
+ tso->gran.sparkname = 0;
+ tso->gran.startedat = CURRENT_TIME;
+ tso->gran.exported = 0;
+ tso->gran.basicblocks = 0;
+ tso->gran.allocs = 0;
+ tso->gran.exectime = 0;
+ tso->gran.fetchtime = 0;
+ tso->gran.fetchcount = 0;
+ tso->gran.blocktime = 0;
+ tso->gran.blockcount = 0;
+ tso->gran.blockedat = 0;
+ tso->gran.globalsparks = 0;
+ tso->gran.localsparks = 0;
+ if (RtsFlags.GranFlags.Light)
+ tso->gran.clock = Now; /* local clock */
+ else
+ tso->gran.clock = 0;
+
+ IF_DEBUG(gran,printTSO(tso));
+#elif defined(PAR)
+# if defined(DEBUG)
+ tso->par.magic = TSO_MAGIC; // debugging only
+# endif
+ tso->par.sparkname = 0;
+ tso->par.startedat = CURRENT_TIME;
+ tso->par.exported = 0;
+ tso->par.basicblocks = 0;
+ tso->par.allocs = 0;
+ tso->par.exectime = 0;
+ tso->par.fetchtime = 0;
+ tso->par.fetchcount = 0;
+ tso->par.blocktime = 0;
+ tso->par.blockcount = 0;
+ tso->par.blockedat = 0;
+ tso->par.globalsparks = 0;
+ tso->par.localsparks = 0;
+#endif
+#if defined(GRAN)
+ globalGranStats.tot_threads_created++;
+ globalGranStats.threads_created_on_PE[CurrentProc]++;
+ globalGranStats.tot_sq_len += spark_queue_len(CurrentProc);
+ globalGranStats.tot_sq_probes++;
+#elif defined(PAR)
+ // collect parallel global statistics (currently done together with GC stats)
+ if (RtsFlags.ParFlags.ParStats.Global &&
+ RtsFlags.GcFlags.giveStats > NO_GC_STATS) {
+ //fprintf(stderr, "Creating thread %d @ %11.2f\n", tso->id, usertime());
+ globalParStats.tot_threads_created++;
+ }
+#endif
+
+#if defined(GRAN)
+ IF_GRAN_DEBUG(pri,
+ belch("==__ schedule: Created TSO %d (%p);",
+ CurrentProc, tso, tso->id));
+#elif defined(PAR)
+ IF_PAR_DEBUG(verbose,
+ belch("==__ schedule: Created TSO %d (%p); %d threads active",
+ tso->id, tso, advisory_thread_count));
+#else
+ IF_DEBUG(scheduler,sched_belch("created thread %ld, stack size = %lx words",
+ tso->id, tso->stack_size));
+#endif
+ return tso;
}
+#if defined(PAR)
+/* RFP:
+ all parallel thread creation calls should fall through the following routine.
+*/
+StgTSO *
+createSparkThread(rtsSpark spark)
+{ StgTSO *tso;
+ ASSERT(spark != (rtsSpark)NULL);
+ if (advisory_thread_count >= RtsFlags.ParFlags.maxThreads)
+ { threadsIgnored++;
+ barf("{createSparkThread}Daq ghuH: refusing to create another thread; no more than %d threads allowed (currently %d)",
+ RtsFlags.ParFlags.maxThreads, advisory_thread_count);
+ return END_TSO_QUEUE;
+ }
+ else
+ { threadsCreated++;
+ tso = createThread(RtsFlags.GcFlags.initialStkSize);
+ if (tso==END_TSO_QUEUE)
+ barf("createSparkThread: Cannot create TSO");
+#if defined(DIST)
+ tso->priority = AdvisoryPriority;
+#endif
+ pushClosure(tso,spark);
+ PUSH_ON_RUN_QUEUE(tso);
+ advisory_thread_count++;
+ }
+ return tso;
+}
+#endif
-/* -----------------------------------------------------------------------------
+/*
+ Turn a spark into a thread.
+ ToDo: fix for SMP (needs to acquire SCHED_MUTEX!)
+*/
+#if defined(PAR)
+StgTSO *
+activateSpark (rtsSpark spark)
+{
+ StgTSO *tso;
+
+ tso = createSparkThread(spark);
+ if (RtsFlags.ParFlags.ParStats.Full) {
+ //ASSERT(run_queue_hd == END_TSO_QUEUE); // I think ...
+ IF_PAR_DEBUG(verbose,
+ belch("==^^ activateSpark: turning spark of closure %p (%s) into a thread",
+ (StgClosure *)spark, info_type((StgClosure *)spark)));
+ }
+ // ToDo: fwd info on local/global spark to thread -- HWL
+ // tso->gran.exported = spark->exported;
+ // tso->gran.locked = !spark->global;
+ // tso->gran.sparkname = spark->name;
+
+ return tso;
+}
+#endif
+
+static SchedulerStatus waitThread_(/*out*/StgMainThread* m,
+ Capability *initialCapability
+ );
+
+
+/* ---------------------------------------------------------------------------
* scheduleThread()
*
* scheduleThread puts a thread on the head of the runnable queue.
* The caller of scheduleThread must create the thread using e.g.
* createThread and push an appropriate closure
* on this thread's stack before the scheduler is invoked.
- * -------------------------------------------------------------------------- */
+ * ------------------------------------------------------------------------ */
+
+static void scheduleThread_ (StgTSO* tso);
void
-scheduleThread(StgTSO *tso)
+scheduleThread_(StgTSO *tso)
{
- ACQUIRE_LOCK(&sched_mutex);
-
- /* Put the new thread on the head of the runnable queue. The caller
- * better push an appropriate closure on this thread's stack
- * beforehand. In the SMP case, the thread may start running as
- * soon as we release the scheduler lock below.
- */
- PUSH_ON_RUN_QUEUE(tso);
+ // Precondition: sched_mutex must be held.
+ // The thread goes at the *end* of the run-queue, to avoid possible
+ // starvation of any threads already on the queue.
+ APPEND_TO_RUN_QUEUE(tso);
THREAD_RUNNABLE();
+}
- IF_DEBUG(scheduler,printTSO(tso));
+void
+scheduleThread(StgTSO* tso)
+{
+ ACQUIRE_LOCK(&sched_mutex);
+ scheduleThread_(tso);
RELEASE_LOCK(&sched_mutex);
}
+#if defined(RTS_SUPPORTS_THREADS)
+static Condition bound_cond_cache;
+static int bound_cond_cache_full = 0;
+#endif
-/* -----------------------------------------------------------------------------
- * startTasks()
- *
- * Start up Posix threads to run each of the scheduler tasks.
- * I believe the task ids are not needed in the system as defined.
- * KH @ 25/10/99
- * -------------------------------------------------------------------------- */
-#ifdef SMP
-static void *
-taskStart( void *arg STG_UNUSED )
+SchedulerStatus
+scheduleWaitThread(StgTSO* tso, /*[out]*/HaskellObj* ret,
+ Capability *initialCapability)
{
- schedule();
- return NULL;
-}
+ // Precondition: sched_mutex must be held
+ StgMainThread *m;
+
+ m = stgMallocBytes(sizeof(StgMainThread), "waitThread");
+ m->tso = tso;
+ tso->main = m;
+ m->ret = ret;
+ m->stat = NoStatus;
+ m->link = main_threads;
+ m->prev = NULL;
+ if (main_threads != NULL) {
+ main_threads->prev = m;
+ }
+ main_threads = m;
+
+#if defined(RTS_SUPPORTS_THREADS)
+ // Allocating a new condition for each thread is expensive, so we
+ // cache one. This is a pretty feeble hack, but it helps speed up
+ // consecutive call-ins quite a bit.
+ if (bound_cond_cache_full) {
+ m->bound_thread_cond = bound_cond_cache;
+ bound_cond_cache_full = 0;
+ } else {
+ initCondition(&m->bound_thread_cond);
+ }
#endif
-/* -----------------------------------------------------------------------------
+ /* Put the thread on the main-threads list prior to scheduling the TSO.
+ Failure to do so introduces a race condition in the MT case (as
+ identified by Wolfgang Thaller), whereby the new task/OS thread
+ created by scheduleThread_() would complete prior to the thread
+ that spawned it managed to put 'itself' on the main-threads list.
+ The upshot of it all being that the worker thread wouldn't get to
+ signal the completion of the its work item for the main thread to
+ see (==> it got stuck waiting.) -- sof 6/02.
+ */
+ IF_DEBUG(scheduler, sched_belch("waiting for thread (%d)", tso->id));
+
+ APPEND_TO_RUN_QUEUE(tso);
+ // NB. Don't call THREAD_RUNNABLE() here, because the thread is
+ // bound and only runnable by *this* OS thread, so waking up other
+ // workers will just slow things down.
+
+ return waitThread_(m, initialCapability);
+}
+
+/* ---------------------------------------------------------------------------
* initScheduler()
*
* Initialise the scheduler. This resets all the queues - if the
* queues contained any threads, they'll be garbage collected at the
* next pass.
*
- * This now calls startTasks(), so should only be called once! KH @ 25/10/99
- * -------------------------------------------------------------------------- */
+ * ------------------------------------------------------------------------ */
-#ifdef SMP
-static void
-term_handler(int sig STG_UNUSED)
+void
+initScheduler(void)
{
- stat_workerStop();
- ACQUIRE_LOCK(&term_mutex);
- await_death--;
- RELEASE_LOCK(&term_mutex);
- pthread_exit(NULL);
-}
-#endif
+#if defined(GRAN)
+ nat i;
-void initScheduler(void)
-{
+ for (i=0; i<=MAX_PROC; i++) {
+ run_queue_hds[i] = END_TSO_QUEUE;
+ run_queue_tls[i] = END_TSO_QUEUE;
+ blocked_queue_hds[i] = END_TSO_QUEUE;
+ blocked_queue_tls[i] = END_TSO_QUEUE;
+ ccalling_threadss[i] = END_TSO_QUEUE;
+ sleeping_queue = END_TSO_QUEUE;
+ }
+#else
run_queue_hd = END_TSO_QUEUE;
run_queue_tl = END_TSO_QUEUE;
blocked_queue_hd = END_TSO_QUEUE;
blocked_queue_tl = END_TSO_QUEUE;
+ sleeping_queue = END_TSO_QUEUE;
+#endif
suspended_ccalling_threads = END_TSO_QUEUE;
main_threads = NULL;
+ all_threads = END_TSO_QUEUE;
context_switch = 0;
interrupted = 0;
- enteredCAFs = END_CAF_LIST;
-
- /* Install the SIGHUP handler */
-#ifdef SMP
- {
- struct sigaction action,oact;
+ RtsFlags.ConcFlags.ctxtSwitchTicks =
+ RtsFlags.ConcFlags.ctxtSwitchTime / TICK_MILLISECS;
+
+#if defined(RTS_SUPPORTS_THREADS)
+ /* Initialise the mutex and condition variables used by
+ * the scheduler. */
+ initMutex(&sched_mutex);
+ initMutex(&term_mutex);
+#endif
+
+ ACQUIRE_LOCK(&sched_mutex);
- action.sa_handler = term_handler;
- sigemptyset(&action.sa_mask);
- action.sa_flags = 0;
- if (sigaction(SIGTERM, &action, &oact) != 0) {
- barf("can't install TERM handler");
- }
- }
+ /* A capability holds the state a native thread needs in
+ * order to execute STG code. At least one capability is
+ * floating around (only SMP builds have more than one).
+ */
+ initCapabilities();
+
+#if defined(RTS_SUPPORTS_THREADS)
+ /* start our haskell execution tasks */
+ startTaskManager(0,taskStart);
#endif
-#ifdef SMP
- /* Allocate N Capabilities */
- {
- nat i;
- Capability *cap, *prev;
- cap = NULL;
- prev = NULL;
- for (i = 0; i < RtsFlags.ConcFlags.nNodes; i++) {
- cap = stgMallocBytes(sizeof(Capability), "initScheduler:capabilities");
- cap->link = prev;
- prev = cap;
- }
- free_capabilities = cap;
- n_free_capabilities = RtsFlags.ConcFlags.nNodes;
- }
- IF_DEBUG(scheduler,fprintf(stderr,"schedule: Allocated %d capabilities\n",
- n_free_capabilities););
+#if /* defined(SMP) ||*/ defined(PAR)
+ initSparkPools();
#endif
+
+ RELEASE_LOCK(&sched_mutex);
}
-#ifdef SMP
void
-startTasks( void )
+exitScheduler( void )
{
- nat i;
- int r;
- pthread_t tid;
-
- /* make some space for saving all the thread ids */
- task_ids = stgMallocBytes(RtsFlags.ConcFlags.nNodes * sizeof(task_info),
- "initScheduler:task_ids");
-
- /* and create all the threads */
- for (i = 0; i < RtsFlags.ConcFlags.nNodes; i++) {
- r = pthread_create(&tid,NULL,taskStart,NULL);
- if (r != 0) {
- barf("startTasks: Can't create new Posix thread");
- }
- task_ids[i].id = tid;
- task_ids[i].mut_time = 0.0;
- task_ids[i].mut_etime = 0.0;
- task_ids[i].gc_time = 0.0;
- task_ids[i].gc_etime = 0.0;
- task_ids[i].elapsedtimestart = elapsedtime();
- IF_DEBUG(scheduler,fprintf(stderr,"schedule: Started task: %ld\n",tid););
- }
-}
-#endif
-
-void
-exitScheduler( void )
-{
-#ifdef SMP
- nat i;
-
- /* Don't want to use pthread_cancel, since we'd have to install
- * these silly exception handlers (pthread_cleanup_{push,pop}) around
- * all our locks.
- */
-#if 0
- /* Cancel all our tasks */
- for (i = 0; i < RtsFlags.ConcFlags.nNodes; i++) {
- pthread_cancel(task_ids[i].id);
- }
-
- /* Wait for all the tasks to terminate */
- for (i = 0; i < RtsFlags.ConcFlags.nNodes; i++) {
- IF_DEBUG(scheduler,fprintf(stderr,"schedule: waiting for task %ld\n",
- task_ids[i].id));
- pthread_join(task_ids[i].id, NULL);
- }
-#endif
-
- /* Send 'em all a SIGHUP. That should shut 'em up.
- */
- await_death = RtsFlags.ConcFlags.nNodes;
- for (i = 0; i < RtsFlags.ConcFlags.nNodes; i++) {
- pthread_kill(task_ids[i].id,SIGTERM);
- }
- while (await_death > 0) {
- sched_yield();
- }
+#if defined(RTS_SUPPORTS_THREADS)
+ stopTaskManager();
#endif
+ shutting_down_scheduler = rtsTrue;
}
-/* -----------------------------------------------------------------------------
+/* ----------------------------------------------------------------------------
Managing the per-task allocation areas.
Each capability comes with an allocation area. These are
fixed-length block lists into which allocation can be done.
ToDo: no support for two-space collection at the moment???
- -------------------------------------------------------------------------- */
-
-/* -----------------------------------------------------------------------------
- * waitThread is the external interface for running a new computataion
- * and waiting for the result.
- *
- * In the non-SMP case, we create a new main thread, push it on the
- * main-thread stack, and invoke the scheduler to run it. The
- * scheduler will return when the top main thread on the stack has
- * completed or died, and fill in the necessary fields of the
- * main_thread structure.
- *
- * In the SMP case, we create a main thread as before, but we then
- * create a new condition variable and sleep on it. When our new
- * main thread has completed, we'll be woken up and the status/result
- * will be in the main_thread struct.
- * -------------------------------------------------------------------------- */
+ ------------------------------------------------------------------------- */
+static
SchedulerStatus
-waitThread(StgTSO *tso, /*out*/StgClosure **ret)
+waitThread_(StgMainThread* m, Capability *initialCapability)
{
- StgMainThread *m;
SchedulerStatus stat;
- ACQUIRE_LOCK(&sched_mutex);
-
- m = stgMallocBytes(sizeof(StgMainThread), "waitThread");
-
- m->tso = tso;
- m->ret = ret;
- m->stat = NoStatus;
-#ifdef SMP
- pthread_cond_init(&m->wakeup, NULL);
-#endif
+ // Precondition: sched_mutex must be held.
+ IF_DEBUG(scheduler, sched_belch("new main thread (%d)", m->tso->id));
- m->link = main_threads;
- main_threads = m;
-
- IF_DEBUG(scheduler, fprintf(stderr, "schedule: new main thread (%d)\n",
- m->tso->id));
-
-#ifdef SMP
- do {
- pthread_cond_wait(&m->wakeup, &sched_mutex);
- } while (m->stat == NoStatus);
+#if defined(GRAN)
+ /* GranSim specific init */
+ CurrentTSO = m->tso; // the TSO to run
+ procStatus[MainProc] = Busy; // status of main PE
+ CurrentProc = MainProc; // PE to run it on
+ schedule(m,initialCapability);
#else
- schedule();
+ schedule(m,initialCapability);
ASSERT(m->stat != NoStatus);
#endif
stat = m->stat;
-#ifdef SMP
- pthread_cond_destroy(&m->wakeup);
+#if defined(RTS_SUPPORTS_THREADS)
+ // Free the condition variable, returning it to the cache if possible.
+ if (!bound_cond_cache_full) {
+ bound_cond_cache = m->bound_thread_cond;
+ bound_cond_cache_full = 1;
+ } else {
+ closeCondition(&m->bound_thread_cond);
+ }
#endif
- free(m);
- RELEASE_LOCK(&sched_mutex);
- return stat;
-}
-
-/* -----------------------------------------------------------------------------
- Debugging: why is a thread blocked
- -------------------------------------------------------------------------- */
+ IF_DEBUG(scheduler, sched_belch("main thread (%d) finished", m->tso->id));
+ stgFree(m);
-#ifdef DEBUG
-void printThreadBlockage(StgTSO *tso)
-{
- switch (tso->why_blocked) {
- case BlockedOnRead:
- fprintf(stderr,"blocked on read from fd %d", tso->block_info.fd);
- break;
- case BlockedOnWrite:
- fprintf(stderr,"blocked on write to fd %d", tso->block_info.fd);
- break;
- case BlockedOnDelay:
- fprintf(stderr,"blocked on delay of %d ms", tso->block_info.delay);
- break;
- case BlockedOnMVar:
- fprintf(stderr,"blocked on an MVar");
- break;
- case BlockedOnBlackHole:
- fprintf(stderr,"blocked on a black hole");
- break;
- case NotBlocked:
- fprintf(stderr,"not blocked");
- break;
- }
+ // Postcondition: sched_mutex still held
+ return stat;
}
-#endif
-/* -----------------------------------------------------------------------------
+/* ---------------------------------------------------------------------------
Where are the roots that we know about?
- all the threads on the runnable queue
- all the threads on the blocked queue
+ - all the threads on the sleeping queue
- all the thread currently executing a _ccall_GC
- all the "main threads"
- -------------------------------------------------------------------------- */
+ ------------------------------------------------------------------------ */
/* This has to be protected either by the scheduler monitor, or by the
garbage collection monitor (probably the latter).
KH @ 25/10/99
*/
-static void GetRoots(void)
+void
+GetRoots( evac_fn evac )
{
- StgMainThread *m;
+#if defined(GRAN)
+ {
+ nat i;
+ for (i=0; i<=RtsFlags.GranFlags.proc; i++) {
+ if ((run_queue_hds[i] != END_TSO_QUEUE) && ((run_queue_hds[i] != NULL)))
+ evac((StgClosure **)&run_queue_hds[i]);
+ if ((run_queue_tls[i] != END_TSO_QUEUE) && ((run_queue_tls[i] != NULL)))
+ evac((StgClosure **)&run_queue_tls[i]);
+
+ if ((blocked_queue_hds[i] != END_TSO_QUEUE) && ((blocked_queue_hds[i] != NULL)))
+ evac((StgClosure **)&blocked_queue_hds[i]);
+ if ((blocked_queue_tls[i] != END_TSO_QUEUE) && ((blocked_queue_tls[i] != NULL)))
+ evac((StgClosure **)&blocked_queue_tls[i]);
+ if ((ccalling_threadss[i] != END_TSO_QUEUE) && ((ccalling_threadss[i] != NULL)))
+ evac((StgClosure **)&ccalling_threads[i]);
+ }
+ }
- run_queue_hd = (StgTSO *)MarkRoot((StgClosure *)run_queue_hd);
- run_queue_tl = (StgTSO *)MarkRoot((StgClosure *)run_queue_tl);
+ markEventQueue();
- blocked_queue_hd = (StgTSO *)MarkRoot((StgClosure *)blocked_queue_hd);
- blocked_queue_tl = (StgTSO *)MarkRoot((StgClosure *)blocked_queue_tl);
+#else /* !GRAN */
+ if (run_queue_hd != END_TSO_QUEUE) {
+ ASSERT(run_queue_tl != END_TSO_QUEUE);
+ evac((StgClosure **)&run_queue_hd);
+ evac((StgClosure **)&run_queue_tl);
+ }
+
+ if (blocked_queue_hd != END_TSO_QUEUE) {
+ ASSERT(blocked_queue_tl != END_TSO_QUEUE);
+ evac((StgClosure **)&blocked_queue_hd);
+ evac((StgClosure **)&blocked_queue_tl);
+ }
+
+ if (sleeping_queue != END_TSO_QUEUE) {
+ evac((StgClosure **)&sleeping_queue);
+ }
+#endif
- for (m = main_threads; m != NULL; m = m->link) {
- m->tso = (StgTSO *)MarkRoot((StgClosure *)m->tso);
+ if (suspended_ccalling_threads != END_TSO_QUEUE) {
+ evac((StgClosure **)&suspended_ccalling_threads);
}
- suspended_ccalling_threads =
- (StgTSO *)MarkRoot((StgClosure *)suspended_ccalling_threads);
+
+#if defined(PAR) || defined(GRAN)
+ markSparkQueue(evac);
+#endif
+
+#if defined(RTS_USER_SIGNALS)
+ // mark the signal handlers (signals should be already blocked)
+ markSignalHandlers(evac);
+#endif
}
/* -----------------------------------------------------------------------------
This needs to be protected by the GC condition variable above. KH.
-------------------------------------------------------------------------- */
-void (*extra_roots)(void);
+static void (*extra_roots)(evac_fn);
void
performGC(void)
{
- GarbageCollect(GetRoots);
+ /* Obligated to hold this lock upon entry */
+ ACQUIRE_LOCK(&sched_mutex);
+ GarbageCollect(GetRoots,rtsFalse);
+ RELEASE_LOCK(&sched_mutex);
+}
+
+void
+performMajorGC(void)
+{
+ ACQUIRE_LOCK(&sched_mutex);
+ GarbageCollect(GetRoots,rtsTrue);
+ RELEASE_LOCK(&sched_mutex);
}
static void
-AllRoots(void)
+AllRoots(evac_fn evac)
{
- GetRoots(); /* the scheduler's roots */
- extra_roots(); /* the user's roots */
+ GetRoots(evac); // the scheduler's roots
+ extra_roots(evac); // the user's roots
}
void
-performGCWithRoots(void (*get_roots)(void))
+performGCWithRoots(void (*get_roots)(evac_fn))
{
+ ACQUIRE_LOCK(&sched_mutex);
extra_roots = get_roots;
-
- GarbageCollect(AllRoots);
+ GarbageCollect(AllRoots,rtsFalse);
+ RELEASE_LOCK(&sched_mutex);
}
/* -----------------------------------------------------------------------------
Stack overflow
- If the thread has reached its maximum stack size,
- then bomb out. Otherwise relocate the TSO into a larger chunk of
- memory and adjust its stack size appropriately.
+ If the thread has reached its maximum stack size, then raise the
+ StackOverflow exception in the offending thread. Otherwise
+ relocate the TSO into a larger chunk of memory and adjust its stack
+ size appropriately.
-------------------------------------------------------------------------- */
static StgTSO *
threadStackOverflow(StgTSO *tso)
{
- nat new_stack_size, new_tso_size, diff, stack_words;
+ nat new_stack_size, new_tso_size, stack_words;
StgPtr new_sp;
StgTSO *dest;
+ IF_DEBUG(sanity,checkTSO(tso));
if (tso->stack_size >= tso->max_stack_size) {
-#if 0
- /* If we're debugging, just print out the top of the stack */
- printStackChunk(tso->sp, stg_min(tso->stack+tso->stack_size,
- tso->sp+64));
-#endif
-#ifdef INTERPRETER
- fprintf(stderr, "fatal: stack overflow in Hugs; aborting\n" );
- exit(1);
-#else
+
+ IF_DEBUG(gc,
+ belch("@@ threadStackOverflow of TSO %d (%p): stack too large (now %ld; max is %ld)",
+ tso->id, tso, tso->stack_size, tso->max_stack_size);
+ /* If we're debugging, just print out the top of the stack */
+ printStackChunk(tso->sp, stg_min(tso->stack+tso->stack_size,
+ tso->sp+64)));
+
/* Send this thread the StackOverflow exception */
- raiseAsync(tso, (StgClosure *)&stackOverflow_closure);
-#endif
+ raiseAsync(tso, (StgClosure *)stackOverflow_closure);
return tso;
}
new_tso_size = round_to_mblocks(new_tso_size); /* Be MBLOCK-friendly */
new_stack_size = new_tso_size - TSO_STRUCT_SIZEW;
- IF_DEBUG(scheduler, fprintf(stderr,"schedule: increasing stack size from %d words to %d.\n", tso->stack_size, new_stack_size));
+ IF_DEBUG(scheduler, fprintf(stderr,"== sched: increasing stack size from %d words to %d.\n", tso->stack_size, new_stack_size));
dest = (StgTSO *)allocate(new_tso_size);
- TICK_ALLOC_TSO(new_tso_size-sizeofW(StgTSO),0);
+ TICK_ALLOC_TSO(new_stack_size,0);
/* copy the TSO block and the old stack into the new area */
memcpy(dest,tso,TSO_STRUCT_SIZE);
memcpy(new_sp, tso->sp, stack_words * sizeof(W_));
/* relocate the stack pointers... */
- diff = (P_)new_sp - (P_)tso->sp; /* In *words* */
- dest->su = (StgUpdateFrame *) ((P_)dest->su + diff);
- dest->sp = new_sp;
- dest->splim = (P_)dest->splim + (nat)((P_)dest - (P_)tso);
+ dest->sp = new_sp;
dest->stack_size = new_stack_size;
- /* and relocate the update frame list */
- relocate_TSO(tso, dest);
-
- /* Mark the old one as dead so we don't try to scavenge it during
- * garbage collection (the TSO will likely be on a mutables list in
- * some generation, but it'll get collected soon enough). It's
- * important to set the sp and su values to just beyond the end of
- * the stack, so we don't attempt to scavenge any part of the dead
- * TSO's stack.
+ /* Mark the old TSO as relocated. We have to check for relocated
+ * TSOs in the garbage collector and any primops that deal with TSOs.
+ *
+ * It's important to set the sp value to just beyond the end
+ * of the stack, so we don't attempt to scavenge any part of the
+ * dead TSO's stack.
*/
- tso->whatNext = ThreadKilled;
+ tso->what_next = ThreadRelocated;
+ tso->link = dest;
tso->sp = (P_)&(tso->stack[tso->stack_size]);
- tso->su = (StgUpdateFrame *)tso->sp;
tso->why_blocked = NotBlocked;
dest->mut_link = NULL;
+ IF_PAR_DEBUG(verbose,
+ belch("@@ threadStackOverflow of TSO %d (now at %p): stack size increased to %ld",
+ tso->id, tso, tso->stack_size);
+ /* If we're debugging, just print out the top of the stack */
+ printStackChunk(tso->sp, stg_min(tso->stack+tso->stack_size,
+ tso->sp+64)));
+
IF_DEBUG(sanity,checkTSO(tso));
#if 0
IF_DEBUG(scheduler,printTSO(dest));
#endif
-#if 0
- /* This will no longer work: KH */
- if (tso == MainTSO) { /* hack */
- MainTSO = dest;
- }
-#endif
return dest;
}
-/* -----------------------------------------------------------------------------
+/* ---------------------------------------------------------------------------
Wake up a queue that was blocked on some resource.
- -------------------------------------------------------------------------- */
+ ------------------------------------------------------------------------ */
+
+#if defined(GRAN)
+STATIC_INLINE void
+unblockCount ( StgBlockingQueueElement *bqe, StgClosure *node )
+{
+}
+#elif defined(PAR)
+STATIC_INLINE void
+unblockCount ( StgBlockingQueueElement *bqe, StgClosure *node )
+{
+ /* write RESUME events to log file and
+ update blocked and fetch time (depending on type of the orig closure) */
+ if (RtsFlags.ParFlags.ParStats.Full) {
+ DumpRawGranEvent(CURRENT_PROC, CURRENT_PROC,
+ GR_RESUMEQ, ((StgTSO *)bqe), ((StgTSO *)bqe)->block_info.closure,
+ 0, 0 /* spark_queue_len(ADVISORY_POOL) */);
+ if (EMPTY_RUN_QUEUE())
+ emitSchedule = rtsTrue;
+
+ switch (get_itbl(node)->type) {
+ case FETCH_ME_BQ:
+ ((StgTSO *)bqe)->par.fetchtime += CURRENT_TIME-((StgTSO *)bqe)->par.blockedat;
+ break;
+ case RBH:
+ case FETCH_ME:
+ case BLACKHOLE_BQ:
+ ((StgTSO *)bqe)->par.blocktime += CURRENT_TIME-((StgTSO *)bqe)->par.blockedat;
+ break;
+#ifdef DIST
+ case MVAR:
+ break;
+#endif
+ default:
+ barf("{unblockOneLocked}Daq Qagh: unexpected closure in blocking queue");
+ }
+ }
+}
+#endif
+
+#if defined(GRAN)
+static StgBlockingQueueElement *
+unblockOneLocked(StgBlockingQueueElement *bqe, StgClosure *node)
+{
+ StgTSO *tso;
+ PEs node_loc, tso_loc;
+
+ node_loc = where_is(node); // should be lifted out of loop
+ tso = (StgTSO *)bqe; // wastes an assignment to get the type right
+ tso_loc = where_is((StgClosure *)tso);
+ if (IS_LOCAL_TO(PROCS(node),tso_loc)) { // TSO is local
+ /* !fake_fetch => TSO is on CurrentProc is same as IS_LOCAL_TO */
+ ASSERT(CurrentProc!=node_loc || tso_loc==CurrentProc);
+ CurrentTime[CurrentProc] += RtsFlags.GranFlags.Costs.lunblocktime;
+ // insertThread(tso, node_loc);
+ new_event(tso_loc, tso_loc, CurrentTime[CurrentProc],
+ ResumeThread,
+ tso, node, (rtsSpark*)NULL);
+ tso->link = END_TSO_QUEUE; // overwrite link just to be sure
+ // len_local++;
+ // len++;
+ } else { // TSO is remote (actually should be FMBQ)
+ CurrentTime[CurrentProc] += RtsFlags.GranFlags.Costs.mpacktime +
+ RtsFlags.GranFlags.Costs.gunblocktime +
+ RtsFlags.GranFlags.Costs.latency;
+ new_event(tso_loc, CurrentProc, CurrentTime[CurrentProc],
+ UnblockThread,
+ tso, node, (rtsSpark*)NULL);
+ tso->link = END_TSO_QUEUE; // overwrite link just to be sure
+ // len++;
+ }
+ /* the thread-queue-overhead is accounted for in either Resume or UnblockThread */
+ IF_GRAN_DEBUG(bq,
+ fprintf(stderr," %s TSO %d (%p) [PE %d] (block_info.closure=%p) (next=%p) ,",
+ (node_loc==tso_loc ? "Local" : "Global"),
+ tso->id, tso, CurrentProc, tso->block_info.closure, tso->link));
+ tso->block_info.closure = NULL;
+ IF_DEBUG(scheduler,belch("-- Waking up thread %ld (%p)",
+ tso->id, tso));
+}
+#elif defined(PAR)
+static StgBlockingQueueElement *
+unblockOneLocked(StgBlockingQueueElement *bqe, StgClosure *node)
+{
+ StgBlockingQueueElement *next;
+
+ switch (get_itbl(bqe)->type) {
+ case TSO:
+ ASSERT(((StgTSO *)bqe)->why_blocked != NotBlocked);
+ /* if it's a TSO just push it onto the run_queue */
+ next = bqe->link;
+ ((StgTSO *)bqe)->link = END_TSO_QUEUE; // debugging?
+ APPEND_TO_RUN_QUEUE((StgTSO *)bqe);
+ THREAD_RUNNABLE();
+ unblockCount(bqe, node);
+ /* reset blocking status after dumping event */
+ ((StgTSO *)bqe)->why_blocked = NotBlocked;
+ break;
+ case BLOCKED_FETCH:
+ /* if it's a BLOCKED_FETCH put it on the PendingFetches list */
+ next = bqe->link;
+ bqe->link = (StgBlockingQueueElement *)PendingFetches;
+ PendingFetches = (StgBlockedFetch *)bqe;
+ break;
+
+# if defined(DEBUG)
+ /* can ignore this case in a non-debugging setup;
+ see comments on RBHSave closures above */
+ case CONSTR:
+ /* check that the closure is an RBHSave closure */
+ ASSERT(get_itbl((StgClosure *)bqe) == &stg_RBH_Save_0_info ||
+ get_itbl((StgClosure *)bqe) == &stg_RBH_Save_1_info ||
+ get_itbl((StgClosure *)bqe) == &stg_RBH_Save_2_info);
+ break;
+
+ default:
+ barf("{unblockOneLocked}Daq Qagh: Unexpected IP (%#lx; %s) in blocking queue at %#lx\n",
+ get_itbl((StgClosure *)bqe), info_type((StgClosure *)bqe),
+ (StgClosure *)bqe);
+# endif
+ }
+ IF_PAR_DEBUG(bq, fprintf(stderr, ", %p (%s)", bqe, info_type((StgClosure*)bqe)));
+ return next;
+}
+
+#else /* !GRAN && !PAR */
static StgTSO *
unblockOneLocked(StgTSO *tso)
{
ASSERT(tso->why_blocked != NotBlocked);
tso->why_blocked = NotBlocked;
next = tso->link;
- PUSH_ON_RUN_QUEUE(tso);
+ tso->link = END_TSO_QUEUE;
+ APPEND_TO_RUN_QUEUE(tso);
THREAD_RUNNABLE();
-#ifdef SMP
- IF_DEBUG(scheduler,belch("schedule (task %ld): waking up thread %ld",
- pthread_self(), tso->id));
-#else
- IF_DEBUG(scheduler,belch("schedule: waking up thread %ld", tso->id));
-#endif
+ IF_DEBUG(scheduler,sched_belch("waking up thread %ld", tso->id));
return next;
}
+#endif
-inline StgTSO *
+#if defined(GRAN) || defined(PAR)
+INLINE_ME StgBlockingQueueElement *
+unblockOne(StgBlockingQueueElement *bqe, StgClosure *node)
+{
+ ACQUIRE_LOCK(&sched_mutex);
+ bqe = unblockOneLocked(bqe, node);
+ RELEASE_LOCK(&sched_mutex);
+ return bqe;
+}
+#else
+INLINE_ME StgTSO *
unblockOne(StgTSO *tso)
{
ACQUIRE_LOCK(&sched_mutex);
RELEASE_LOCK(&sched_mutex);
return tso;
}
+#endif
+
+#if defined(GRAN)
+void
+awakenBlockedQueue(StgBlockingQueueElement *q, StgClosure *node)
+{
+ StgBlockingQueueElement *bqe;
+ PEs node_loc;
+ nat len = 0;
+
+ IF_GRAN_DEBUG(bq,
+ belch("##-_ AwBQ for node %p on PE %d @ %ld by TSO %d (%p): ", \
+ node, CurrentProc, CurrentTime[CurrentProc],
+ CurrentTSO->id, CurrentTSO));
+
+ node_loc = where_is(node);
+
+ ASSERT(q == END_BQ_QUEUE ||
+ get_itbl(q)->type == TSO || // q is either a TSO or an RBHSave
+ get_itbl(q)->type == CONSTR); // closure (type constructor)
+ ASSERT(is_unique(node));
+
+ /* FAKE FETCH: magically copy the node to the tso's proc;
+ no Fetch necessary because in reality the node should not have been
+ moved to the other PE in the first place
+ */
+ if (CurrentProc!=node_loc) {
+ IF_GRAN_DEBUG(bq,
+ belch("## node %p is on PE %d but CurrentProc is %d (TSO %d); assuming fake fetch and adjusting bitmask (old: %#x)",
+ node, node_loc, CurrentProc, CurrentTSO->id,
+ // CurrentTSO, where_is(CurrentTSO),
+ node->header.gran.procs));
+ node->header.gran.procs = (node->header.gran.procs) | PE_NUMBER(CurrentProc);
+ IF_GRAN_DEBUG(bq,
+ belch("## new bitmask of node %p is %#x",
+ node, node->header.gran.procs));
+ if (RtsFlags.GranFlags.GranSimStats.Global) {
+ globalGranStats.tot_fake_fetches++;
+ }
+ }
+
+ bqe = q;
+ // ToDo: check: ASSERT(CurrentProc==node_loc);
+ while (get_itbl(bqe)->type==TSO) { // q != END_TSO_QUEUE) {
+ //next = bqe->link;
+ /*
+ bqe points to the current element in the queue
+ next points to the next element in the queue
+ */
+ //tso = (StgTSO *)bqe; // wastes an assignment to get the type right
+ //tso_loc = where_is(tso);
+ len++;
+ bqe = unblockOneLocked(bqe, node);
+ }
+
+ /* if this is the BQ of an RBH, we have to put back the info ripped out of
+ the closure to make room for the anchor of the BQ */
+ if (bqe!=END_BQ_QUEUE) {
+ ASSERT(get_itbl(node)->type == RBH && get_itbl(bqe)->type == CONSTR);
+ /*
+ ASSERT((info_ptr==&RBH_Save_0_info) ||
+ (info_ptr==&RBH_Save_1_info) ||
+ (info_ptr==&RBH_Save_2_info));
+ */
+ /* cf. convertToRBH in RBH.c for writing the RBHSave closure */
+ ((StgRBH *)node)->blocking_queue = (StgBlockingQueueElement *)((StgRBHSave *)bqe)->payload[0];
+ ((StgRBH *)node)->mut_link = (StgMutClosure *)((StgRBHSave *)bqe)->payload[1];
+
+ IF_GRAN_DEBUG(bq,
+ belch("## Filled in RBH_Save for %p (%s) at end of AwBQ",
+ node, info_type(node)));
+ }
+
+ /* statistics gathering */
+ if (RtsFlags.GranFlags.GranSimStats.Global) {
+ // globalGranStats.tot_bq_processing_time += bq_processing_time;
+ globalGranStats.tot_bq_len += len; // total length of all bqs awakened
+ // globalGranStats.tot_bq_len_local += len_local; // same for local TSOs only
+ globalGranStats.tot_awbq++; // total no. of bqs awakened
+ }
+ IF_GRAN_DEBUG(bq,
+ fprintf(stderr,"## BQ Stats of %p: [%d entries] %s\n",
+ node, len, (bqe!=END_BQ_QUEUE) ? "RBH" : ""));
+}
+#elif defined(PAR)
+void
+awakenBlockedQueue(StgBlockingQueueElement *q, StgClosure *node)
+{
+ StgBlockingQueueElement *bqe;
+
+ ACQUIRE_LOCK(&sched_mutex);
+
+ IF_PAR_DEBUG(verbose,
+ belch("##-_ AwBQ for node %p on [%x]: ",
+ node, mytid));
+#ifdef DIST
+ //RFP
+ if(get_itbl(q)->type == CONSTR || q==END_BQ_QUEUE) {
+ IF_PAR_DEBUG(verbose, belch("## ... nothing to unblock so lets just return. RFP (BUG?)"));
+ return;
+ }
+#endif
+
+ ASSERT(q == END_BQ_QUEUE ||
+ get_itbl(q)->type == TSO ||
+ get_itbl(q)->type == BLOCKED_FETCH ||
+ get_itbl(q)->type == CONSTR);
+
+ bqe = q;
+ while (get_itbl(bqe)->type==TSO ||
+ get_itbl(bqe)->type==BLOCKED_FETCH) {
+ bqe = unblockOneLocked(bqe, node);
+ }
+ RELEASE_LOCK(&sched_mutex);
+}
+
+#else /* !GRAN && !PAR */
+
+void
+awakenBlockedQueueNoLock(StgTSO *tso)
+{
+ while (tso != END_TSO_QUEUE) {
+ tso = unblockOneLocked(tso);
+ }
+}
void
awakenBlockedQueue(StgTSO *tso)
}
RELEASE_LOCK(&sched_mutex);
}
+#endif
-/* -----------------------------------------------------------------------------
+/* ---------------------------------------------------------------------------
Interrupt execution
- usually called inside a signal handler so it mustn't do anything fancy.
- -------------------------------------------------------------------------- */
+ ------------------------------------------------------------------------ */
void
interruptStgRts(void)
{
interrupted = 1;
context_switch = 1;
+#ifdef RTS_SUPPORTS_THREADS
+ wakeBlockedWorkerThread();
+#endif
}
/* -----------------------------------------------------------------------------
This is for use when we raise an exception in another thread, which
may be blocked.
+ This has nothing to do with the UnblockThread event in GranSim. -- HWL
-------------------------------------------------------------------------- */
+#if defined(GRAN) || defined(PAR)
+/*
+ NB: only the type of the blocking queue is different in GranSim and GUM
+ the operations on the queue-elements are the same
+ long live polymorphism!
+
+ Locks: sched_mutex is held upon entry and exit.
+
+*/
static void
unblockThread(StgTSO *tso)
{
- StgTSO *t, **last;
+ StgBlockingQueueElement *t, **last;
- ACQUIRE_LOCK(&sched_mutex);
switch (tso->why_blocked) {
case NotBlocked:
case BlockedOnMVar:
ASSERT(get_itbl(tso->block_info.closure)->type == MVAR);
{
+ StgBlockingQueueElement *last_tso = END_BQ_QUEUE;
+ StgMVar *mvar = (StgMVar *)(tso->block_info.closure);
+
+ last = (StgBlockingQueueElement **)&mvar->head;
+ for (t = (StgBlockingQueueElement *)mvar->head;
+ t != END_BQ_QUEUE;
+ last = &t->link, last_tso = t, t = t->link) {
+ if (t == (StgBlockingQueueElement *)tso) {
+ *last = (StgBlockingQueueElement *)tso->link;
+ if (mvar->tail == tso) {
+ mvar->tail = (StgTSO *)last_tso;
+ }
+ goto done;
+ }
+ }
+ barf("unblockThread (MVAR): TSO not found");
+ }
+
+ case BlockedOnBlackHole:
+ ASSERT(get_itbl(tso->block_info.closure)->type == BLACKHOLE_BQ);
+ {
+ StgBlockingQueue *bq = (StgBlockingQueue *)(tso->block_info.closure);
+
+ last = &bq->blocking_queue;
+ for (t = bq->blocking_queue;
+ t != END_BQ_QUEUE;
+ last = &t->link, t = t->link) {
+ if (t == (StgBlockingQueueElement *)tso) {
+ *last = (StgBlockingQueueElement *)tso->link;
+ goto done;
+ }
+ }
+ barf("unblockThread (BLACKHOLE): TSO not found");
+ }
+
+ case BlockedOnException:
+ {
+ StgTSO *target = tso->block_info.tso;
+
+ ASSERT(get_itbl(target)->type == TSO);
+
+ if (target->what_next == ThreadRelocated) {
+ target = target->link;
+ ASSERT(get_itbl(target)->type == TSO);
+ }
+
+ ASSERT(target->blocked_exceptions != NULL);
+
+ last = (StgBlockingQueueElement **)&target->blocked_exceptions;
+ for (t = (StgBlockingQueueElement *)target->blocked_exceptions;
+ t != END_BQ_QUEUE;
+ last = &t->link, t = t->link) {
+ ASSERT(get_itbl(t)->type == TSO);
+ if (t == (StgBlockingQueueElement *)tso) {
+ *last = (StgBlockingQueueElement *)tso->link;
+ goto done;
+ }
+ }
+ barf("unblockThread (Exception): TSO not found");
+ }
+
+ case BlockedOnRead:
+ case BlockedOnWrite:
+#if defined(mingw32_TARGET_OS)
+ case BlockedOnDoProc:
+#endif
+ {
+ /* take TSO off blocked_queue */
+ StgBlockingQueueElement *prev = NULL;
+ for (t = (StgBlockingQueueElement *)blocked_queue_hd; t != END_BQ_QUEUE;
+ prev = t, t = t->link) {
+ if (t == (StgBlockingQueueElement *)tso) {
+ if (prev == NULL) {
+ blocked_queue_hd = (StgTSO *)t->link;
+ if ((StgBlockingQueueElement *)blocked_queue_tl == t) {
+ blocked_queue_tl = END_TSO_QUEUE;
+ }
+ } else {
+ prev->link = t->link;
+ if ((StgBlockingQueueElement *)blocked_queue_tl == t) {
+ blocked_queue_tl = (StgTSO *)prev;
+ }
+ }
+ goto done;
+ }
+ }
+ barf("unblockThread (I/O): TSO not found");
+ }
+
+ case BlockedOnDelay:
+ {
+ /* take TSO off sleeping_queue */
+ StgBlockingQueueElement *prev = NULL;
+ for (t = (StgBlockingQueueElement *)sleeping_queue; t != END_BQ_QUEUE;
+ prev = t, t = t->link) {
+ if (t == (StgBlockingQueueElement *)tso) {
+ if (prev == NULL) {
+ sleeping_queue = (StgTSO *)t->link;
+ } else {
+ prev->link = t->link;
+ }
+ goto done;
+ }
+ }
+ barf("unblockThread (delay): TSO not found");
+ }
+
+ default:
+ barf("unblockThread");
+ }
+
+ done:
+ tso->link = END_TSO_QUEUE;
+ tso->why_blocked = NotBlocked;
+ tso->block_info.closure = NULL;
+ PUSH_ON_RUN_QUEUE(tso);
+}
+#else
+static void
+unblockThread(StgTSO *tso)
+{
+ StgTSO *t, **last;
+
+ /* To avoid locking unnecessarily. */
+ if (tso->why_blocked == NotBlocked) {
+ return;
+ }
+
+ switch (tso->why_blocked) {
+
+ case BlockedOnMVar:
+ ASSERT(get_itbl(tso->block_info.closure)->type == MVAR);
+ {
StgTSO *last_tso = END_TSO_QUEUE;
StgMVar *mvar = (StgMVar *)(tso->block_info.closure);
barf("unblockThread (BLACKHOLE): TSO not found");
}
- case BlockedOnDelay:
+ case BlockedOnException:
+ {
+ StgTSO *target = tso->block_info.tso;
+
+ ASSERT(get_itbl(target)->type == TSO);
+
+ while (target->what_next == ThreadRelocated) {
+ target = target->link;
+ ASSERT(get_itbl(target)->type == TSO);
+ }
+
+ ASSERT(target->blocked_exceptions != NULL);
+
+ last = &target->blocked_exceptions;
+ for (t = target->blocked_exceptions; t != END_TSO_QUEUE;
+ last = &t->link, t = t->link) {
+ ASSERT(get_itbl(t)->type == TSO);
+ if (t == tso) {
+ *last = tso->link;
+ goto done;
+ }
+ }
+ barf("unblockThread (Exception): TSO not found");
+ }
+
case BlockedOnRead:
case BlockedOnWrite:
+#if defined(mingw32_TARGET_OS)
+ case BlockedOnDoProc:
+#endif
{
StgTSO *prev = NULL;
for (t = blocked_queue_hd; t != END_TSO_QUEUE;
barf("unblockThread (I/O): TSO not found");
}
+ case BlockedOnDelay:
+ {
+ StgTSO *prev = NULL;
+ for (t = sleeping_queue; t != END_TSO_QUEUE;
+ prev = t, t = t->link) {
+ if (t == tso) {
+ if (prev == NULL) {
+ sleeping_queue = t->link;
+ } else {
+ prev->link = t->link;
+ }
+ goto done;
+ }
+ }
+ barf("unblockThread (delay): TSO not found");
+ }
+
default:
barf("unblockThread");
}
tso->link = END_TSO_QUEUE;
tso->why_blocked = NotBlocked;
tso->block_info.closure = NULL;
- PUSH_ON_RUN_QUEUE(tso);
- RELEASE_LOCK(&sched_mutex);
+ APPEND_TO_RUN_QUEUE(tso);
}
+#endif
/* -----------------------------------------------------------------------------
* raiseAsync()
* the top of the stack.
*
* How exactly do we save all the active computations? We create an
- * AP_UPD for every UpdateFrame on the stack. Entering one of these
- * AP_UPDs pushes everything from the corresponding update frame
+ * AP_STACK for every UpdateFrame on the stack. Entering one of these
+ * AP_STACKs pushes everything from the corresponding update frame
* upwards onto the stack. (Actually, it pushes everything up to the
- * next update frame plus a pointer to the next AP_UPD object.
- * Entering the next AP_UPD object pushes more onto the stack until we
- * reach the last AP_UPD object - at which point the stack should look
+ * next update frame plus a pointer to the next AP_STACK object.
+ * Entering the next AP_STACK object pushes more onto the stack until we
+ * reach the last AP_STACK object - at which point the stack should look
* exactly as it did when we killed the TSO and we can continue
* execution by entering the closure on top of the stack.
*
* CATCH_FRAME on the stack. In either case, we strip the entire
* stack and replace the thread with a zombie.
*
+ * Locks: sched_mutex held upon entry nor exit.
+ *
* -------------------------------------------------------------------------- */
void
raiseAsync(tso,NULL);
}
-void
-raiseAsync(StgTSO *tso, StgClosure *exception)
-{
- StgUpdateFrame* su = tso->su;
- StgPtr sp = tso->sp;
-
- /* Thread already dead? */
- if (tso->whatNext == ThreadComplete || tso->whatNext == ThreadKilled) {
- return;
- }
-
- IF_DEBUG(scheduler, belch("schedule: Raising exception in thread %ld.", tso->id));
+#ifdef FORKPROCESS_PRIMOP_SUPPORTED
+static void
+deleteThreadImmediately(StgTSO *tso)
+{ // for forkProcess only:
+ // delete thread without giving it a chance to catch the KillThread exception
- /* Remove it from any blocking queues */
- unblockThread(tso);
+ if (tso->what_next == ThreadComplete || tso->what_next == ThreadKilled) {
+ return;
+ }
- /* The stack freezing code assumes there's a closure pointer on
- * the top of the stack. This isn't always the case with compiled
- * code, so we have to push a dummy closure on the top which just
- * returns to the next return address on the stack.
- */
- if ( LOOKS_LIKE_GHC_INFO((void*)*sp) ) {
- *(--sp) = (W_)&dummy_ret_closure;
+ if (tso->why_blocked != BlockedOnCCall &&
+ tso->why_blocked != BlockedOnCCall_NoUnblockExc) {
+ unblockThread(tso);
}
- while (1) {
- int words = ((P_)su - (P_)sp) - 1;
- nat i;
- StgAP_UPD * ap;
+ tso->what_next = ThreadKilled;
+}
+#endif
- /* If we find a CATCH_FRAME, and we've got an exception to raise,
- * then build PAP(handler,exception), and leave it on top of
- * the stack ready to enter.
- */
- if (get_itbl(su)->type == CATCH_FRAME && exception != NULL) {
- StgCatchFrame *cf = (StgCatchFrame *)su;
- /* we've got an exception to raise, so let's pass it to the
- * handler in this frame.
- */
- ap = (StgAP_UPD *)allocate(sizeofW(StgPAP) + 1);
- TICK_ALLOC_UPD_PAP(2,0);
- SET_HDR(ap,&PAP_info,cf->header.prof.ccs);
-
- ap->n_args = 1;
- ap->fun = cf->handler;
- ap->payload[0] = (P_)exception;
-
- /* sp currently points to the word above the CATCH_FRAME on the
- * stack. Replace the CATCH_FRAME with a pointer to the new handler
- * application.
- */
- sp += sizeofW(StgCatchFrame);
- sp[0] = (W_)ap;
- tso->su = cf->link;
- tso->sp = sp;
- tso->whatNext = ThreadEnterGHC;
- return;
+void
+raiseAsyncWithLock(StgTSO *tso, StgClosure *exception)
+{
+ /* When raising async exs from contexts where sched_mutex isn't held;
+ use raiseAsyncWithLock(). */
+ ACQUIRE_LOCK(&sched_mutex);
+ raiseAsync(tso,exception);
+ RELEASE_LOCK(&sched_mutex);
+}
+
+void
+raiseAsync(StgTSO *tso, StgClosure *exception)
+{
+ StgRetInfoTable *info;
+ StgPtr sp;
+
+ // Thread already dead?
+ if (tso->what_next == ThreadComplete || tso->what_next == ThreadKilled) {
+ return;
}
- /* First build an AP_UPD consisting of the stack chunk above the
- * current update frame, with the top word on the stack as the
- * fun field.
- */
- ap = (StgAP_UPD *)allocate(AP_sizeW(words));
+ IF_DEBUG(scheduler,
+ sched_belch("raising exception in thread %ld.", tso->id));
- ASSERT(words >= 0);
+ // Remove it from any blocking queues
+ unblockThread(tso);
+
+ sp = tso->sp;
- ap->n_args = words;
- ap->fun = (StgClosure *)sp[0];
- sp++;
- for(i=0; i < (nat)words; ++i) {
- ap->payload[i] = (P_)*sp++;
+ // The stack freezing code assumes there's a closure pointer on
+ // the top of the stack, so we have to arrange that this is the case...
+ //
+ if (sp[0] == (W_)&stg_enter_info) {
+ sp++;
+ } else {
+ sp--;
+ sp[0] = (W_)&stg_dummy_ret_closure;
}
-
- switch (get_itbl(su)->type) {
-
- case UPDATE_FRAME:
- {
- SET_HDR(ap,&AP_UPD_info,su->header.prof.ccs /* ToDo */);
- TICK_ALLOC_UP_THK(words+1,0);
-
- IF_DEBUG(scheduler,
- fprintf(stderr, "schedule: Updating ");
- printPtr((P_)su->updatee);
- fprintf(stderr, " with ");
- printObj((StgClosure *)ap);
- );
-
- /* Replace the updatee with an indirection - happily
- * this will also wake up any threads currently
- * waiting on the result.
- */
- UPD_IND_NOLOCK(su->updatee,ap); /* revert the black hole */
- su = su->link;
- sp += sizeofW(StgUpdateFrame) -1;
- sp[0] = (W_)ap; /* push onto stack */
- break;
- }
-
- case CATCH_FRAME:
- {
- StgCatchFrame *cf = (StgCatchFrame *)su;
- StgClosure* o;
-
- /* We want a PAP, not an AP_UPD. Fortunately, the
- * layout's the same.
- */
- SET_HDR(ap,&PAP_info,su->header.prof.ccs /* ToDo */);
- TICK_ALLOC_UPD_PAP(words+1,0);
+
+ while (1) {
+ nat i;
+
+ // 1. Let the top of the stack be the "current closure"
+ //
+ // 2. Walk up the stack until we find either an UPDATE_FRAME or a
+ // CATCH_FRAME.
+ //
+ // 3. If it's an UPDATE_FRAME, then make an AP_STACK containing the
+ // current closure applied to the chunk of stack up to (but not
+ // including) the update frame. This closure becomes the "current
+ // closure". Go back to step 2.
+ //
+ // 4. If it's a CATCH_FRAME, then leave the exception handler on
+ // top of the stack applied to the exception.
+ //
+ // 5. If it's a STOP_FRAME, then kill the thread.
- /* now build o = FUN(catch,ap,handler) */
- o = (StgClosure *)allocate(sizeofW(StgClosure)+2);
- TICK_ALLOC_FUN(2,0);
- SET_HDR(o,&catch_info,su->header.prof.ccs /* ToDo */);
- o->payload[0] = (StgClosure *)ap;
- o->payload[1] = cf->handler;
+ StgPtr frame;
- IF_DEBUG(scheduler,
- fprintf(stderr, "schedule: Built ");
- printObj((StgClosure *)o);
- );
+ frame = sp + 1;
+ info = get_ret_itbl((StgClosure *)frame);
- /* pop the old handler and put o on the stack */
- su = cf->link;
- sp += sizeofW(StgCatchFrame) - 1;
- sp[0] = (W_)o;
- break;
- }
-
- case SEQ_FRAME:
- {
- StgSeqFrame *sf = (StgSeqFrame *)su;
- StgClosure* o;
-
- SET_HDR(ap,&PAP_info,su->header.prof.ccs /* ToDo */);
- TICK_ALLOC_UPD_PAP(words+1,0);
+ while (info->i.type != UPDATE_FRAME
+ && (info->i.type != CATCH_FRAME || exception == NULL)
+ && info->i.type != STOP_FRAME) {
+ frame += stack_frame_sizeW((StgClosure *)frame);
+ info = get_ret_itbl((StgClosure *)frame);
+ }
- /* now build o = FUN(seq,ap) */
- o = (StgClosure *)allocate(sizeofW(StgClosure)+1);
- TICK_ALLOC_SE_THK(1,0);
- SET_HDR(o,&seq_info,su->header.prof.ccs /* ToDo */);
- payloadCPtr(o,0) = (StgClosure *)ap;
+ switch (info->i.type) {
+
+ case CATCH_FRAME:
+ // If we find a CATCH_FRAME, and we've got an exception to raise,
+ // then build the THUNK raise(exception), and leave it on
+ // top of the CATCH_FRAME ready to enter.
+ //
+ {
+#ifdef PROFILING
+ StgCatchFrame *cf = (StgCatchFrame *)frame;
+#endif
+ StgClosure *raise;
+
+ // we've got an exception to raise, so let's pass it to the
+ // handler in this frame.
+ //
+ raise = (StgClosure *)allocate(sizeofW(StgClosure)+1);
+ TICK_ALLOC_SE_THK(1,0);
+ SET_HDR(raise,&stg_raise_info,cf->header.prof.ccs);
+ raise->payload[0] = exception;
+
+ // throw away the stack from Sp up to the CATCH_FRAME.
+ //
+ sp = frame - 1;
+
+ /* Ensure that async excpetions are blocked now, so we don't get
+ * a surprise exception before we get around to executing the
+ * handler.
+ */
+ if (tso->blocked_exceptions == NULL) {
+ tso->blocked_exceptions = END_TSO_QUEUE;
+ }
+
+ /* Put the newly-built THUNK on top of the stack, ready to execute
+ * when the thread restarts.
+ */
+ sp[0] = (W_)raise;
+ sp[-1] = (W_)&stg_enter_info;
+ tso->sp = sp-1;
+ tso->what_next = ThreadRunGHC;
+ IF_DEBUG(sanity, checkTSO(tso));
+ return;
+ }
- IF_DEBUG(scheduler,
- fprintf(stderr, "schedule: Built ");
- printObj((StgClosure *)o);
- );
+ case UPDATE_FRAME:
+ {
+ StgAP_STACK * ap;
+ nat words;
+
+ // First build an AP_STACK consisting of the stack chunk above the
+ // current update frame, with the top word on the stack as the
+ // fun field.
+ //
+ words = frame - sp - 1;
+ ap = (StgAP_STACK *)allocate(PAP_sizeW(words));
+
+ ap->size = words;
+ ap->fun = (StgClosure *)sp[0];
+ sp++;
+ for(i=0; i < (nat)words; ++i) {
+ ap->payload[i] = (StgClosure *)*sp++;
+ }
+
+ SET_HDR(ap,&stg_AP_STACK_info,
+ ((StgClosure *)frame)->header.prof.ccs /* ToDo */);
+ TICK_ALLOC_UP_THK(words+1,0);
+
+ IF_DEBUG(scheduler,
+ fprintf(stderr, "sched: Updating ");
+ printPtr((P_)((StgUpdateFrame *)frame)->updatee);
+ fprintf(stderr, " with ");
+ printObj((StgClosure *)ap);
+ );
+
+ // Replace the updatee with an indirection - happily
+ // this will also wake up any threads currently
+ // waiting on the result.
+ //
+ // Warning: if we're in a loop, more than one update frame on
+ // the stack may point to the same object. Be careful not to
+ // overwrite an IND_OLDGEN in this case, because we'll screw
+ // up the mutable lists. To be on the safe side, don't
+ // overwrite any kind of indirection at all. See also
+ // threadSqueezeStack in GC.c, where we have to make a similar
+ // check.
+ //
+ if (!closure_IND(((StgUpdateFrame *)frame)->updatee)) {
+ // revert the black hole
+ UPD_IND_NOLOCK(((StgUpdateFrame *)frame)->updatee,
+ (StgClosure *)ap);
+ }
+ sp += sizeofW(StgUpdateFrame) - 1;
+ sp[0] = (W_)ap; // push onto stack
+ break;
+ }
- /* pop the old handler and put o on the stack */
- su = sf->link;
- sp += sizeofW(StgSeqFrame) - 1;
- sp[0] = (W_)o;
- break;
- }
-
- case STOP_FRAME:
- /* We've stripped the entire stack, the thread is now dead. */
- sp += sizeofW(StgStopFrame) - 1;
- sp[0] = (W_)exception; /* save the exception */
- tso->whatNext = ThreadKilled;
- tso->su = (StgUpdateFrame *)(sp+1);
- tso->sp = sp;
- return;
+ case STOP_FRAME:
+ // We've stripped the entire stack, the thread is now dead.
+ sp += sizeofW(StgStopFrame);
+ tso->what_next = ThreadKilled;
+ tso->sp = sp;
+ return;
+
+ default:
+ barf("raiseAsync");
+ }
+ }
+ barf("raiseAsync");
+}
+
+/* -----------------------------------------------------------------------------
+ raiseExceptionHelper
+
+ This function is called by the raise# primitve, just so that we can
+ move some of the tricky bits of raising an exception from C-- into
+ C. Who knows, it might be a useful re-useable thing here too.
+ -------------------------------------------------------------------------- */
+
+StgWord
+raiseExceptionHelper (StgTSO *tso, StgClosure *exception)
+{
+ StgClosure *raise_closure = NULL;
+ StgPtr p, next;
+ StgRetInfoTable *info;
+ //
+ // This closure represents the expression 'raise# E' where E
+ // is the exception raise. It is used to overwrite all the
+ // thunks which are currently under evaluataion.
+ //
+
+ //
+ // LDV profiling: stg_raise_info has THUNK as its closure
+ // type. Since a THUNK takes at least MIN_UPD_SIZE words in its
+ // payload, MIN_UPD_SIZE is more approprate than 1. It seems that
+ // 1 does not cause any problem unless profiling is performed.
+ // However, when LDV profiling goes on, we need to linearly scan
+ // small object pool, where raise_closure is stored, so we should
+ // use MIN_UPD_SIZE.
+ //
+ // raise_closure = (StgClosure *)RET_STGCALL1(P_,allocate,
+ // sizeofW(StgClosure)+1);
+ //
+
+ //
+ // Walk up the stack, looking for the catch frame. On the way,
+ // we update any closures pointed to from update frames with the
+ // raise closure that we just built.
+ //
+ p = tso->sp;
+ while(1) {
+ info = get_ret_itbl((StgClosure *)p);
+ next = p + stack_frame_sizeW((StgClosure *)p);
+ switch (info->i.type) {
+
+ case UPDATE_FRAME:
+ // Only create raise_closure if we need to.
+ if (raise_closure == NULL) {
+ raise_closure =
+ (StgClosure *)allocate(sizeofW(StgClosure)+MIN_UPD_SIZE);
+ SET_HDR(raise_closure, &stg_raise_info, CCCS);
+ raise_closure->payload[0] = exception;
+ }
+ UPD_IND(((StgUpdateFrame *)p)->updatee,raise_closure);
+ p = next;
+ continue;
+
+ case CATCH_FRAME:
+ tso->sp = p;
+ return CATCH_FRAME;
+
+ case STOP_FRAME:
+ tso->sp = p;
+ return STOP_FRAME;
+
+ default:
+ p = next;
+ continue;
+ }
+ }
+}
+
+/* -----------------------------------------------------------------------------
+ resurrectThreads is called after garbage collection on the list of
+ threads found to be garbage. Each of these threads will be woken
+ up and sent a signal: BlockedOnDeadMVar if the thread was blocked
+ on an MVar, or NonTermination if the thread was blocked on a Black
+ Hole.
+
+ Locks: sched_mutex isn't held upon entry nor exit.
+ -------------------------------------------------------------------------- */
+
+void
+resurrectThreads( StgTSO *threads )
+{
+ StgTSO *tso, *next;
+
+ for (tso = threads; tso != END_TSO_QUEUE; tso = next) {
+ next = tso->global_link;
+ tso->global_link = all_threads;
+ all_threads = tso;
+ IF_DEBUG(scheduler, sched_belch("resurrecting thread %d", tso->id));
+
+ switch (tso->why_blocked) {
+ case BlockedOnMVar:
+ case BlockedOnException:
+ /* Called by GC - sched_mutex lock is currently held. */
+ raiseAsync(tso,(StgClosure *)BlockedOnDeadMVar_closure);
+ break;
+ case BlockedOnBlackHole:
+ raiseAsync(tso,(StgClosure *)NonTermination_closure);
+ break;
+ case NotBlocked:
+ /* This might happen if the thread was blocked on a black hole
+ * belonging to a thread that we've just woken up (raiseAsync
+ * can wake up threads, remember...).
+ */
+ continue;
+ default:
+ barf("resurrectThreads: thread blocked in a strange way");
+ }
+ }
+}
+
+/* -----------------------------------------------------------------------------
+ * Blackhole detection: if we reach a deadlock, test whether any
+ * threads are blocked on themselves. Any threads which are found to
+ * be self-blocked get sent a NonTermination exception.
+ *
+ * This is only done in a deadlock situation in order to avoid
+ * performance overhead in the normal case.
+ *
+ * Locks: sched_mutex is held upon entry and exit.
+ * -------------------------------------------------------------------------- */
+
+static void
+detectBlackHoles( void )
+{
+ StgTSO *tso = all_threads;
+ StgClosure *frame;
+ StgClosure *blocked_on;
+ StgRetInfoTable *info;
+
+ for (tso = all_threads; tso != END_TSO_QUEUE; tso = tso->global_link) {
+
+ while (tso->what_next == ThreadRelocated) {
+ tso = tso->link;
+ ASSERT(get_itbl(tso)->type == TSO);
+ }
+ if (tso->why_blocked != BlockedOnBlackHole) {
+ continue;
+ }
+ blocked_on = tso->block_info.closure;
+
+ frame = (StgClosure *)tso->sp;
+
+ while(1) {
+ info = get_ret_itbl(frame);
+ switch (info->i.type) {
+ case UPDATE_FRAME:
+ if (((StgUpdateFrame *)frame)->updatee == blocked_on) {
+ /* We are blocking on one of our own computations, so
+ * send this thread the NonTermination exception.
+ */
+ IF_DEBUG(scheduler,
+ sched_belch("thread %d is blocked on itself", tso->id));
+ raiseAsync(tso, (StgClosure *)NonTermination_closure);
+ goto done;
+ }
+
+ frame = (StgClosure *) ((StgUpdateFrame *)frame + 1);
+ continue;
+
+ case STOP_FRAME:
+ goto done;
+
+ // normal stack frames; do nothing except advance the pointer
+ default:
+ (StgPtr)frame += stack_frame_sizeW(frame);
+ }
+ }
+ done: ;
+ }
+}
+
+/* ----------------------------------------------------------------------------
+ * Debugging: why is a thread blocked
+ * [Also provides useful information when debugging threaded programs
+ * at the Haskell source code level, so enable outside of DEBUG. --sof 7/02]
+ ------------------------------------------------------------------------- */
+
+static
+void
+printThreadBlockage(StgTSO *tso)
+{
+ switch (tso->why_blocked) {
+ case BlockedOnRead:
+ fprintf(stderr,"is blocked on read from fd %d", tso->block_info.fd);
+ break;
+ case BlockedOnWrite:
+ fprintf(stderr,"is blocked on write to fd %d", tso->block_info.fd);
+ break;
+#if defined(mingw32_TARGET_OS)
+ case BlockedOnDoProc:
+ fprintf(stderr,"is blocked on proc (request: %d)", tso->block_info.async_result->reqID);
+ break;
+#endif
+ case BlockedOnDelay:
+ fprintf(stderr,"is blocked until %d", tso->block_info.target);
+ break;
+ case BlockedOnMVar:
+ fprintf(stderr,"is blocked on an MVar");
+ break;
+ case BlockedOnException:
+ fprintf(stderr,"is blocked on delivering an exception to thread %d",
+ tso->block_info.tso->id);
+ break;
+ case BlockedOnBlackHole:
+ fprintf(stderr,"is blocked on a black hole");
+ break;
+ case NotBlocked:
+ fprintf(stderr,"is not blocked");
+ break;
+#if defined(PAR)
+ case BlockedOnGA:
+ fprintf(stderr,"is blocked on global address; local FM_BQ is %p (%s)",
+ tso->block_info.closure, info_type(tso->block_info.closure));
+ break;
+ case BlockedOnGA_NoSend:
+ fprintf(stderr,"is blocked on global address (no send); local FM_BQ is %p (%s)",
+ tso->block_info.closure, info_type(tso->block_info.closure));
+ break;
+#endif
+ case BlockedOnCCall:
+ fprintf(stderr,"is blocked on an external call");
+ break;
+ case BlockedOnCCall_NoUnblockExc:
+ fprintf(stderr,"is blocked on an external call (exceptions were already blocked)");
+ break;
+ default:
+ barf("printThreadBlockage: strange tso->why_blocked: %d for TSO %d (%d)",
+ tso->why_blocked, tso->id, tso);
+ }
+}
+
+static
+void
+printThreadStatus(StgTSO *tso)
+{
+ switch (tso->what_next) {
+ case ThreadKilled:
+ fprintf(stderr,"has been killed");
+ break;
+ case ThreadComplete:
+ fprintf(stderr,"has completed");
+ break;
+ default:
+ printThreadBlockage(tso);
+ }
+}
+
+void
+printAllThreads(void)
+{
+ StgTSO *t;
+ void *label;
+
+# if defined(GRAN)
+ char time_string[TIME_STR_LEN], node_str[NODE_STR_LEN];
+ ullong_format_string(TIME_ON_PROC(CurrentProc),
+ time_string, rtsFalse/*no commas!*/);
+
+ fprintf(stderr, "all threads at [%s]:\n", time_string);
+# elif defined(PAR)
+ char time_string[TIME_STR_LEN], node_str[NODE_STR_LEN];
+ ullong_format_string(CURRENT_TIME,
+ time_string, rtsFalse/*no commas!*/);
+
+ fprintf(stderr,"all threads at [%s]:\n", time_string);
+# else
+ fprintf(stderr,"all threads:\n");
+# endif
+
+ for (t = all_threads; t != END_TSO_QUEUE; t = t->global_link) {
+ fprintf(stderr, "\tthread %d @ %p ", t->id, (void *)t);
+ label = lookupThreadLabel(t->id);
+ if (label) fprintf(stderr,"[\"%s\"] ",(char *)label);
+ printThreadStatus(t);
+ fprintf(stderr,"\n");
+ }
+}
+
+#ifdef DEBUG
+
+/*
+ Print a whole blocking queue attached to node (debugging only).
+*/
+# if defined(PAR)
+void
+print_bq (StgClosure *node)
+{
+ StgBlockingQueueElement *bqe;
+ StgTSO *tso;
+ rtsBool end;
+
+ fprintf(stderr,"## BQ of closure %p (%s): ",
+ node, info_type(node));
+
+ /* should cover all closures that may have a blocking queue */
+ ASSERT(get_itbl(node)->type == BLACKHOLE_BQ ||
+ get_itbl(node)->type == FETCH_ME_BQ ||
+ get_itbl(node)->type == RBH ||
+ get_itbl(node)->type == MVAR);
+
+ ASSERT(node!=(StgClosure*)NULL); // sanity check
+
+ print_bqe(((StgBlockingQueue*)node)->blocking_queue);
+}
+
+/*
+ Print a whole blocking queue starting with the element bqe.
+*/
+void
+print_bqe (StgBlockingQueueElement *bqe)
+{
+ rtsBool end;
+
+ /*
+ NB: In a parallel setup a BQ of an RBH must end with an RBH_Save closure;
+ */
+ for (end = (bqe==END_BQ_QUEUE);
+ !end; // iterate until bqe points to a CONSTR
+ end = (get_itbl(bqe)->type == CONSTR) || (bqe->link==END_BQ_QUEUE),
+ bqe = end ? END_BQ_QUEUE : bqe->link) {
+ ASSERT(bqe != END_BQ_QUEUE); // sanity check
+ ASSERT(bqe != (StgBlockingQueueElement *)NULL); // sanity check
+ /* types of closures that may appear in a blocking queue */
+ ASSERT(get_itbl(bqe)->type == TSO ||
+ get_itbl(bqe)->type == BLOCKED_FETCH ||
+ get_itbl(bqe)->type == CONSTR);
+ /* only BQs of an RBH end with an RBH_Save closure */
+ //ASSERT(get_itbl(bqe)->type != CONSTR || get_itbl(node)->type == RBH);
+
+ switch (get_itbl(bqe)->type) {
+ case TSO:
+ fprintf(stderr," TSO %u (%x),",
+ ((StgTSO *)bqe)->id, ((StgTSO *)bqe));
+ break;
+ case BLOCKED_FETCH:
+ fprintf(stderr," BF (node=%p, ga=((%x, %d, %x)),",
+ ((StgBlockedFetch *)bqe)->node,
+ ((StgBlockedFetch *)bqe)->ga.payload.gc.gtid,
+ ((StgBlockedFetch *)bqe)->ga.payload.gc.slot,
+ ((StgBlockedFetch *)bqe)->ga.weight);
+ break;
+ case CONSTR:
+ fprintf(stderr," %s (IP %p),",
+ (get_itbl(bqe) == &stg_RBH_Save_0_info ? "RBH_Save_0" :
+ get_itbl(bqe) == &stg_RBH_Save_1_info ? "RBH_Save_1" :
+ get_itbl(bqe) == &stg_RBH_Save_2_info ? "RBH_Save_2" :
+ "RBH_Save_?"), get_itbl(bqe));
+ break;
+ default:
+ barf("Unexpected closure type %s in blocking queue", // of %p (%s)",
+ info_type((StgClosure *)bqe)); // , node, info_type(node));
+ break;
+ }
+ } /* for */
+ fputc('\n', stderr);
+}
+# elif defined(GRAN)
+void
+print_bq (StgClosure *node)
+{
+ StgBlockingQueueElement *bqe;
+ PEs node_loc, tso_loc;
+ rtsBool end;
+
+ /* should cover all closures that may have a blocking queue */
+ ASSERT(get_itbl(node)->type == BLACKHOLE_BQ ||
+ get_itbl(node)->type == FETCH_ME_BQ ||
+ get_itbl(node)->type == RBH);
+
+ ASSERT(node!=(StgClosure*)NULL); // sanity check
+ node_loc = where_is(node);
+
+ fprintf(stderr,"## BQ of closure %p (%s) on [PE %d]: ",
+ node, info_type(node), node_loc);
+
+ /*
+ NB: In a parallel setup a BQ of an RBH must end with an RBH_Save closure;
+ */
+ for (bqe = ((StgBlockingQueue*)node)->blocking_queue, end = (bqe==END_BQ_QUEUE);
+ !end; // iterate until bqe points to a CONSTR
+ end = (get_itbl(bqe)->type == CONSTR) || (bqe->link==END_BQ_QUEUE), bqe = end ? END_BQ_QUEUE : bqe->link) {
+ ASSERT(bqe != END_BQ_QUEUE); // sanity check
+ ASSERT(bqe != (StgBlockingQueueElement *)NULL); // sanity check
+ /* types of closures that may appear in a blocking queue */
+ ASSERT(get_itbl(bqe)->type == TSO ||
+ get_itbl(bqe)->type == CONSTR);
+ /* only BQs of an RBH end with an RBH_Save closure */
+ ASSERT(get_itbl(bqe)->type != CONSTR || get_itbl(node)->type == RBH);
+
+ tso_loc = where_is((StgClosure *)bqe);
+ switch (get_itbl(bqe)->type) {
+ case TSO:
+ fprintf(stderr," TSO %d (%p) on [PE %d],",
+ ((StgTSO *)bqe)->id, (StgTSO *)bqe, tso_loc);
+ break;
+ case CONSTR:
+ fprintf(stderr," %s (IP %p),",
+ (get_itbl(bqe) == &stg_RBH_Save_0_info ? "RBH_Save_0" :
+ get_itbl(bqe) == &stg_RBH_Save_1_info ? "RBH_Save_1" :
+ get_itbl(bqe) == &stg_RBH_Save_2_info ? "RBH_Save_2" :
+ "RBH_Save_?"), get_itbl(bqe));
+ break;
default:
- barf("raiseAsync");
+ barf("Unexpected closure type %s in blocking queue of %p (%s)",
+ info_type((StgClosure *)bqe), node, info_type(node));
+ break;
}
+ } /* for */
+ fputc('\n', stderr);
+}
+#else
+/*
+ Nice and easy: only TSOs on the blocking queue
+*/
+void
+print_bq (StgClosure *node)
+{
+ StgTSO *tso;
+
+ ASSERT(node!=(StgClosure*)NULL); // sanity check
+ for (tso = ((StgBlockingQueue*)node)->blocking_queue;
+ tso != END_TSO_QUEUE;
+ tso=tso->link) {
+ ASSERT(tso!=NULL && tso!=END_TSO_QUEUE); // sanity check
+ ASSERT(get_itbl(tso)->type == TSO); // guess what, sanity check
+ fprintf(stderr," TSO %d (%p),", tso->id, tso);
}
- barf("raiseAsync");
+ fputc('\n', stderr);
+}
+# endif
+
+#if defined(PAR)
+static nat
+run_queue_len(void)
+{
+ nat i;
+ StgTSO *tso;
+
+ for (i=0, tso=run_queue_hd;
+ tso != END_TSO_QUEUE;
+ i++, tso=tso->link)
+ /* nothing */
+
+ return i;
+}
+#endif
+
+void
+sched_belch(char *s, ...)
+{
+ va_list ap;
+ va_start(ap,s);
+#ifdef RTS_SUPPORTS_THREADS
+ fprintf(stderr, "sched (task %p): ", osThreadId());
+#elif defined(PAR)
+ fprintf(stderr, "== ");
+#else
+ fprintf(stderr, "sched: ");
+#endif
+ vfprintf(stderr, s, ap);
+ fprintf(stderr, "\n");
+ fflush(stderr);
+ va_end(ap);
}
+#endif /* DEBUG */