#include "Capability.h"
#include "Schedule.h"
#include "Sparks.h"
+#include "Trace.h"
// one global capability, this is the Capability for non-threaded
// builds, and for +RTS -N1
cap->mut_lists[g] = NULL;
}
- cap->free_tvar_wait_queues = END_STM_WAIT_QUEUE;
+ cap->free_tvar_watch_queues = END_STM_WATCH_QUEUE;
+ cap->free_invariant_check_queues = END_INVARIANT_CHECK_QUEUE;
cap->free_trec_chunks = END_STM_CHUNK_LIST;
cap->free_trec_headers = NO_TREC;
cap->transaction_tokens = 0;
initCapability(&capabilities[i], i);
}
- IF_DEBUG(scheduler, sched_belch("allocated %d capabilities",
- n_capabilities));
+ debugTrace(DEBUG_sched, "allocated %d capabilities", n_capabilities);
#else /* !THREADED_RTS */
{
ASSERT_LOCK_HELD(&cap->lock);
ASSERT(task->cap == cap);
- IF_DEBUG(scheduler,
- sched_belch("passing capability %d to %s %p",
- cap->no, task->tso ? "bound task" : "worker",
- (void *)task->id));
+ trace(TRACE_sched | DEBUG_sched,
+ "passing capability %d to %s %p",
+ cap->no, task->tso ? "bound task" : "worker",
+ (void *)task->id);
ACQUIRE_LOCK(&task->lock);
task->wakeup = rtsTrue;
// the wakeup flag is needed because signalCondition() doesn't
// are threads that need to be completed. If the system is
// shutting down, we never create a new worker.
if (sched_state < SCHED_SHUTTING_DOWN || !emptyRunQueue(cap)) {
- IF_DEBUG(scheduler,
- sched_belch("starting new worker on capability %d", cap->no));
+ debugTrace(DEBUG_sched,
+ "starting new worker on capability %d", cap->no);
startWorkerTask(cap, workerStart);
return;
}
}
last_free_capability = cap;
- IF_DEBUG(scheduler, sched_belch("freeing capability %d", cap->no));
+ trace(TRACE_sched | DEBUG_sched, "freeing capability %d", cap->no);
}
void
ACQUIRE_LOCK(&cap->lock);
- IF_DEBUG(scheduler,
- sched_belch("returning; I want capability %d", cap->no));
+ debugTrace(DEBUG_sched, "returning; I want capability %d", cap->no);
if (!cap->running_task) {
// It's free; just grab it
ASSERT_FULL_CAPABILITY_INVARIANTS(cap,task);
- IF_DEBUG(scheduler,
- sched_belch("returning; got capability %d", cap->no));
+ trace(TRACE_sched | DEBUG_sched, "resuming capability %d", cap->no);
*pCap = cap;
#endif
// The fast path has no locking, if we don't enter this while loop
while ( cap->returning_tasks_hd != NULL || !anyWorkForMe(cap,task) ) {
- IF_DEBUG(scheduler, sched_belch("giving up capability %d", cap->no));
+ debugTrace(DEBUG_sched, "giving up capability %d", cap->no);
// We must now release the capability and wait to be woken up
// again.
task->wakeup = rtsFalse;
RELEASE_LOCK(&task->lock);
- IF_DEBUG(scheduler, sched_belch("woken up on capability %d", cap->no));
+ debugTrace(DEBUG_sched, "woken up on capability %d", cap->no);
+
ACQUIRE_LOCK(&cap->lock);
if (cap->running_task != NULL) {
- IF_DEBUG(scheduler, sched_belch("capability %d is owned by another task", cap->no));
+ debugTrace(DEBUG_sched,
+ "capability %d is owned by another task", cap->no);
RELEASE_LOCK(&cap->lock);
continue;
}
break;
}
- IF_DEBUG(scheduler, sched_belch("got capability %d", cap->no));
+ trace(TRACE_sched | DEBUG_sched, "resuming capability %d", cap->no);
ASSERT(cap->running_task == task);
}
{
ASSERT(tso->cap == cap);
ASSERT(tso->bound ? tso->bound->cap == cap : 1);
+ ASSERT_LOCK_HELD(&cap->lock);
+
+ tso->cap = cap;
- ACQUIRE_LOCK(&cap->lock);
if (cap->running_task == NULL) {
// nobody is running this Capability, we can add our thread
// directly onto the run queue and start up a Task to run it.
// start it up
cap->running_task = myTask(); // precond for releaseCapability_()
+ trace(TRACE_sched, "resuming capability %d", cap->no);
releaseCapability_(cap);
} else {
appendToWakeupQueue(cap,tso);
// freed without first checking the wakeup queue (see
// releaseCapability_).
}
+}
+
+void
+wakeupThreadOnCapability_lock (Capability *cap, StgTSO *tso)
+{
+ ACQUIRE_LOCK(&cap->lock);
+ migrateThreadToCapability (cap, tso);
+ RELEASE_LOCK(&cap->lock);
+}
+
+void
+migrateThreadToCapability (Capability *cap, StgTSO *tso)
+{
+ // ASSUMES: cap->lock is held (asserted in wakeupThreadOnCapability)
+ if (tso->bound) {
+ ASSERT(tso->bound->cap == tso->cap);
+ tso->bound->cap = cap;
+ }
+ tso->cap = cap;
+ wakeupThreadOnCapability(cap,tso);
+}
+
+void
+migrateThreadToCapability_lock (Capability *cap, StgTSO *tso)
+{
+ ACQUIRE_LOCK(&cap->lock);
+ migrateThreadToCapability (cap, tso);
RELEASE_LOCK(&cap->lock);
}
ACQUIRE_LOCK(&cap->lock);
if (!cap->running_task) {
if (cap->spare_workers) {
+ trace(TRACE_sched, "resuming capability %d", cap->no);
task = cap->spare_workers;
ASSERT(!task->stopped);
giveCapabilityToTask(cap,task);
task->cap = cap;
- for (i = 0; i < 50; i++) {
- IF_DEBUG(scheduler, sched_belch("shutting down capability %d, attempt %d", cap->no, i));
+ // Loop indefinitely until all the workers have exited and there
+ // are no Haskell threads left. We used to bail out after 50
+ // iterations of this loop, but that occasionally left a worker
+ // running which caused problems later (the closeMutex() below
+ // isn't safe, for one thing).
+
+ for (i = 0; /* i < 50 */; i++) {
+ debugTrace(DEBUG_sched,
+ "shutting down capability %d, attempt %d", cap->no, i);
ACQUIRE_LOCK(&cap->lock);
if (cap->running_task) {
RELEASE_LOCK(&cap->lock);
- IF_DEBUG(scheduler, sched_belch("not owner, yielding"));
+ debugTrace(DEBUG_sched, "not owner, yielding");
yieldThread();
continue;
}
cap->running_task = task;
if (!emptyRunQueue(cap) || cap->spare_workers) {
- IF_DEBUG(scheduler, sched_belch("runnable threads or workers still alive, yielding"));
+ debugTrace(DEBUG_sched,
+ "runnable threads or workers still alive, yielding");
releaseCapability_(cap); // this will wake up a worker
RELEASE_LOCK(&cap->lock);
yieldThread();
continue;
}
- IF_DEBUG(scheduler, sched_belch("capability %d is stopped.", cap->no));
+ debugTrace(DEBUG_sched, "capability %d is stopped.", cap->no);
+ freeCapability(cap);
RELEASE_LOCK(&cap->lock);
break;
}
// we now have the Capability, its run queue and spare workers
// list are both empty.
+
+ // ToDo: we can't drop this mutex, because there might still be
+ // threads performing foreign calls that will eventually try to
+ // return via resumeThread() and attempt to grab cap->lock.
+ // closeMutex(&cap->lock);
}
/* ----------------------------------------------------------------------------
#endif /* THREADED_RTS */
+void
+freeCapability (Capability *cap) {
+ stgFree(cap->mut_lists);
+#if defined(THREADED_RTS) || defined(PARALLEL_HASKELL)
+ freeSparkPool(&cap->r.rSparks);
+#endif
+}