void ConcurrentG1RefineThread::run() {
initialize_in_thread();
wait_for_universe_init();
if (_worker_id >= cg1r()->worker_thread_num()) {
run_young_rs_sampling();
terminate();
}
_vtime_start = os::elapsedVTime();
while (!_should_terminate) {
DirtyCardQueueSet& dcqs = JavaThread::dirty_card_queue_set();
// Wait for work
wait_for_completed_buffers();
if (_should_terminate) {
break;
}
_sts.join();
do {
int curr_buffer_num = (int)dcqs.completed_buffers_num();
// If the number of the buffers falls down into the yellow zone,
// that means that the transition period after the evacuation pause has ended.
if (dcqs.completed_queue_padding() > 0 && curr_buffer_num <= cg1r()->yellow_zone()) {
dcqs.set_completed_queue_padding(0);
}
if (_worker_id > 0 && curr_buffer_num <= _deactivation_threshold) {
// If the number of the buffer has fallen below our threshold
// we should deactivate. The predecessor will reactivate this
// thread should the number of the buffers cross the threshold again.
deactivate();
break;
}
// Check if we need to activate the next thread.
if (_next != NULL && !_next->is_active() && curr_buffer_num > _next->_threshold) {
_next->activate();
}
} while (dcqs.apply_closure_to_completed_buffer(_worker_id + _worker_id_offset, cg1r()->green_zone()));
// We can exit the loop above while being active if there was a yield request.
if (is_active()) {
deactivate();
}
_sts.leave();
if (os::supports_vtime()) {
_vtime_accum = (os::elapsedVTime() - _vtime_start);
} else {
_vtime_accum = 0.0;
}
}
assert(_should_terminate, "just checking");
terminate();
}
void ConcurrentMarkThread::run() {
initialize_in_thread();
wait_for_universe_init();
run_service();
terminate();
}
void G1StringDedupThread::run() {
G1StringDedupStat total_stat;
initialize_in_thread();
wait_for_universe_init();
deduplicate_shared_strings(total_stat);
// Main loop
for (;;) {
G1StringDedupStat stat;
stat.mark_idle();
// Wait for the queue to become non-empty
G1StringDedupQueue::wait();
if (_should_terminate) {
break;
}
{
// Include thread in safepoints
SuspendibleThreadSetJoiner sts_join;
stat.mark_exec();
// Process the queue
for (;;) {
oop java_string = G1StringDedupQueue::pop();
if (java_string == NULL) {
break;
}
G1StringDedupTable::deduplicate(java_string, stat);
// Safepoint this thread if needed
if (sts_join.should_yield()) {
stat.mark_block();
sts_join.yield();
stat.mark_unblock();
}
}
G1StringDedupTable::trim_entry_cache();
stat.mark_done();
// Print statistics
total_stat.add(stat);
print(gclog_or_tty, stat, total_stat);
}
}
terminate();
}
void ConcurrentZFThread::run() {
initialize_in_thread();
Thread* thr_self = Thread::current();
_vtime_start = os::elapsedVTime();
wait_for_universe_init();
G1CollectedHeap* g1 = G1CollectedHeap::heap();
_sts.join();
while (!_should_terminate) {
_sts.leave();
{
MutexLockerEx x(ZF_mon, Mutex::_no_safepoint_check_flag);
// This local variable will hold a region being zero-filled. This
// region will neither be on the unclean or zero-filled lists, and
// will not be available for allocation; thus, we might have an
// allocation fail, causing a full GC, because of this, but this is a
// price we will pay. (In future, we might want to make the fact
// that there's a region being zero-filled apparent to the G1 heap,
// which could then wait for it in this extreme case...)
HeapRegion* to_fill;
while (!g1->should_zf()
|| (to_fill = g1->pop_unclean_region_list_locked()) == NULL)
ZF_mon->wait(Mutex::_no_safepoint_check_flag);
while (to_fill->zero_fill_state() == HeapRegion::ZeroFilling)
ZF_mon->wait(Mutex::_no_safepoint_check_flag);
// So now to_fill is non-NULL and is not ZeroFilling. It might be
// Allocated or ZeroFilled. (The latter could happen if this thread
// starts the zero-filling of a region, but a GC intervenes and
// pushes new regions needing on the front of the filling on the
// front of the list.)
switch (to_fill->zero_fill_state()) {
case HeapRegion::Allocated:
to_fill = NULL;
break;
case HeapRegion::NotZeroFilled:
to_fill->set_zero_fill_in_progress(thr_self);
ZF_mon->unlock();
_sts.join();
processHeapRegion(to_fill);
_sts.leave();
ZF_mon->lock_without_safepoint_check();
if (to_fill->zero_fill_state() == HeapRegion::ZeroFilling
&& to_fill->zero_filler() == thr_self) {
to_fill->set_zero_fill_complete();
(void)g1->put_free_region_on_list_locked(to_fill);
}
break;
case HeapRegion::ZeroFilled:
(void)g1->put_free_region_on_list_locked(to_fill);
break;
case HeapRegion::ZeroFilling:
ShouldNotReachHere();
break;
}
}
_vtime_accum = (os::elapsedVTime() - _vtime_start);
_sts.join();
}
_sts.leave();
assert(_should_terminate, "just checking");
terminate();
}
void ConcurrentMarkThread::run() {
initialize_in_thread();
_vtime_start = os::elapsedVTime();
wait_for_universe_init();
G1CollectedHeap* g1h = G1CollectedHeap::heap();
G1CollectorPolicy* g1_policy = g1h->g1_policy();
G1MMUTracker *mmu_tracker = g1_policy->mmu_tracker();
Thread *current_thread = Thread::current();
while (!_should_terminate) {
// wait until started is set.
sleepBeforeNextCycle();
if (_should_terminate) {
break;
}
{
ResourceMark rm;
HandleMark hm;
double cycle_start = os::elapsedVTime();
// We have to ensure that we finish scanning the root regions
// before the next GC takes place. To ensure this we have to
// make sure that we do not join the STS until the root regions
// have been scanned. If we did then it's possible that a
// subsequent GC could block us from joining the STS and proceed
// without the root regions have been scanned which would be a
// correctness issue.
if (!cm()->has_aborted()) {
_cm->scanRootRegions();
}
double mark_start_sec = os::elapsedTime();
cm_log(G1Log::fine(), true, "[GC concurrent-mark-start]");
int iter = 0;
do {
iter++;
if (!cm()->has_aborted()) {
_cm->markFromRoots();
}
double mark_end_time = os::elapsedVTime();
double mark_end_sec = os::elapsedTime();
_vtime_mark_accum += (mark_end_time - cycle_start);
if (!cm()->has_aborted()) {
if (g1_policy->adaptive_young_list_length()) {
double now = os::elapsedTime();
double remark_prediction_ms = g1_policy->predict_remark_time_ms();
jlong sleep_time_ms = mmu_tracker->when_ms(now, remark_prediction_ms);
os::sleep(current_thread, sleep_time_ms, false);
}
cm_log(G1Log::fine(), true, "[GC concurrent-mark-end, %1.7lf secs]", mark_end_sec - mark_start_sec);
CMCheckpointRootsFinalClosure final_cl(_cm);
VM_CGC_Operation op(&final_cl, "GC remark", true /* needs_pll */);
VMThread::execute(&op);
}
if (cm()->restart_for_overflow()) {
cm_log(G1TraceMarkStackOverflow, true, "Restarting conc marking because of MS overflow in remark (restart #%d).", iter);
cm_log(G1Log::fine(), true, "[GC concurrent-mark-restart-for-overflow]");
}
} while (cm()->restart_for_overflow());
double end_time = os::elapsedVTime();
// Update the total virtual time before doing this, since it will try
// to measure it to get the vtime for this marking. We purposely
// neglect the presumably-short "completeCleanup" phase here.
_vtime_accum = (end_time - _vtime_start);
if (!cm()->has_aborted()) {
if (g1_policy->adaptive_young_list_length()) {
double now = os::elapsedTime();
double cleanup_prediction_ms = g1_policy->predict_cleanup_time_ms();
jlong sleep_time_ms = mmu_tracker->when_ms(now, cleanup_prediction_ms);
os::sleep(current_thread, sleep_time_ms, false);
}
CMCleanUp cl_cl(_cm);
VM_CGC_Operation op(&cl_cl, "GC cleanup", false /* needs_pll */);
VMThread::execute(&op);
} else {
// We don't want to update the marking status if a GC pause
// is already underway.
SuspendibleThreadSetJoiner sts_join;
g1h->collector_state()->set_mark_in_progress(false);
}
// Check if cleanup set the free_regions_coming flag. If it
// hasn't, we can just skip the next step.
if (g1h->free_regions_coming()) {
// The following will finish freeing up any regions that we
// found to be empty during cleanup. We'll do this part
// without joining the suspendible set. If an evacuation pause
// takes place, then we would carry on freeing regions in
// case they are needed by the pause. If a Full GC takes
// place, it would wait for us to process the regions
// reclaimed by cleanup.
double cleanup_start_sec = os::elapsedTime();
cm_log(G1Log::fine(), true, "[GC concurrent-cleanup-start]");
// Now do the concurrent cleanup operation.
_cm->completeCleanup();
// Notify anyone who's waiting that there are no more free
// regions coming. We have to do this before we join the STS
// (in fact, we should not attempt to join the STS in the
// interval between finishing the cleanup pause and clearing
// the free_regions_coming flag) otherwise we might deadlock:
// a GC worker could be blocked waiting for the notification
// whereas this thread will be blocked for the pause to finish
// while it's trying to join the STS, which is conditional on
// the GC workers finishing.
g1h->reset_free_regions_coming();
double cleanup_end_sec = os::elapsedTime();
cm_log(G1Log::fine(), true, "[GC concurrent-cleanup-end, %1.7lf secs]", cleanup_end_sec - cleanup_start_sec);
}
guarantee(cm()->cleanup_list_is_empty(),
"at this point there should be no regions on the cleanup list");
// There is a tricky race before recording that the concurrent
// cleanup has completed and a potential Full GC starting around
// the same time. We want to make sure that the Full GC calls
// abort() on concurrent mark after
// record_concurrent_mark_cleanup_completed(), since abort() is
// the method that will reset the concurrent mark state. If we
// end up calling record_concurrent_mark_cleanup_completed()
// after abort() then we might incorrectly undo some of the work
// abort() did. Checking the has_aborted() flag after joining
// the STS allows the correct ordering of the two methods. There
// are two scenarios:
//
// a) If we reach here before the Full GC, the fact that we have
// joined the STS means that the Full GC cannot start until we
// leave the STS, so record_concurrent_mark_cleanup_completed()
// will complete before abort() is called.
//
// b) If we reach here during the Full GC, we'll be held up from
// joining the STS until the Full GC is done, which means that
// abort() will have completed and has_aborted() will return
// true to prevent us from calling
// record_concurrent_mark_cleanup_completed() (and, in fact, it's
// not needed any more as the concurrent mark state has been
// already reset).
{
SuspendibleThreadSetJoiner sts_join;
if (!cm()->has_aborted()) {
g1_policy->record_concurrent_mark_cleanup_completed();
} else {
cm_log(G1Log::fine(), false, "[GC concurrent-mark-abort]");
}
}
// We now want to allow clearing of the marking bitmap to be
// suspended by a collection pause.
// We may have aborted just before the remark. Do not bother clearing the
// bitmap then, as it has been done during mark abort.
if (!cm()->has_aborted()) {
_cm->clearNextBitmap();
} else {
assert(!G1VerifyBitmaps || _cm->nextMarkBitmapIsClear(), "Next mark bitmap must be clear");
}
}
// Update the number of full collections that have been
// completed. This will also notify the FullGCCount_lock in case a
// Java thread is waiting for a full GC to happen (e.g., it
// called System.gc() with +ExplicitGCInvokesConcurrent).
{
SuspendibleThreadSetJoiner sts_join;
g1h->increment_old_marking_cycles_completed(true /* concurrent */);
g1h->register_concurrent_cycle_end();
}
}
assert(_should_terminate, "just checking");
terminate();
}
void ConcurrentMarkThread::run() {
initialize_in_thread();
_vtime_start = os::elapsedVTime();
wait_for_universe_init();
G1CollectedHeap* g1h = G1CollectedHeap::heap();
G1CollectorPolicy* g1_policy = g1h->g1_policy();
G1MMUTracker *mmu_tracker = g1_policy->mmu_tracker();
Thread *current_thread = Thread::current();
while (!_should_terminate) {
// wait until started is set.
sleepBeforeNextCycle();
{
ResourceMark rm;
HandleMark hm;
double cycle_start = os::elapsedVTime();
double mark_start_sec = os::elapsedTime();
char verbose_str[128];
if (PrintGC) {
gclog_or_tty->date_stamp(PrintGCDateStamps);
gclog_or_tty->stamp(PrintGCTimeStamps);
gclog_or_tty->print_cr("[GC concurrent-mark-start]");
}
if (!g1_policy->in_young_gc_mode()) {
// this ensures the flag is not set if we bail out of the marking
// cycle; normally the flag is cleared immediately after cleanup
g1h->set_marking_complete();
if (g1_policy->adaptive_young_list_length()) {
double now = os::elapsedTime();
double init_prediction_ms = g1_policy->predict_init_time_ms();
jlong sleep_time_ms = mmu_tracker->when_ms(now, init_prediction_ms);
os::sleep(current_thread, sleep_time_ms, false);
}
// We don't have to skip here if we've been asked to restart, because
// in the worst case we just enqueue a new VM operation to start a
// marking. Note that the init operation resets has_aborted()
CMCheckpointRootsInitialClosure init_cl(_cm);
strcpy(verbose_str, "GC initial-mark");
VM_CGC_Operation op(&init_cl, verbose_str);
VMThread::execute(&op);
}
int iter = 0;
do {
iter++;
if (!cm()->has_aborted()) {
_cm->markFromRoots();
}
double mark_end_time = os::elapsedVTime();
double mark_end_sec = os::elapsedTime();
_vtime_mark_accum += (mark_end_time - cycle_start);
if (!cm()->has_aborted()) {
if (g1_policy->adaptive_young_list_length()) {
double now = os::elapsedTime();
double remark_prediction_ms = g1_policy->predict_remark_time_ms();
jlong sleep_time_ms = mmu_tracker->when_ms(now, remark_prediction_ms);
os::sleep(current_thread, sleep_time_ms, false);
}
if (PrintGC) {
gclog_or_tty->date_stamp(PrintGCDateStamps);
gclog_or_tty->stamp(PrintGCTimeStamps);
gclog_or_tty->print_cr("[GC concurrent-mark-end, %1.7lf sec]",
mark_end_sec - mark_start_sec);
}
CMCheckpointRootsFinalClosure final_cl(_cm);
sprintf(verbose_str, "GC remark");
VM_CGC_Operation op(&final_cl, verbose_str);
VMThread::execute(&op);
}
if (cm()->restart_for_overflow() &&
G1TraceMarkStackOverflow) {
gclog_or_tty->print_cr("Restarting conc marking because of MS overflow "
"in remark (restart #%d).", iter);
}
if (cm()->restart_for_overflow()) {
if (PrintGC) {
gclog_or_tty->date_stamp(PrintGCDateStamps);
gclog_or_tty->stamp(PrintGCTimeStamps);
gclog_or_tty->print_cr("[GC concurrent-mark-restart-for-overflow]");
}
}
} while (cm()->restart_for_overflow());
double counting_start_time = os::elapsedVTime();
// YSR: These look dubious (i.e. redundant) !!! FIX ME
slt()->manipulatePLL(SurrogateLockerThread::acquirePLL);
slt()->manipulatePLL(SurrogateLockerThread::releaseAndNotifyPLL);
if (!cm()->has_aborted()) {
double count_start_sec = os::elapsedTime();
if (PrintGC) {
gclog_or_tty->date_stamp(PrintGCDateStamps);
gclog_or_tty->stamp(PrintGCTimeStamps);
gclog_or_tty->print_cr("[GC concurrent-count-start]");
}
_sts.join();
_cm->calcDesiredRegions();
_sts.leave();
if (!cm()->has_aborted()) {
double count_end_sec = os::elapsedTime();
if (PrintGC) {
gclog_or_tty->date_stamp(PrintGCDateStamps);
gclog_or_tty->stamp(PrintGCTimeStamps);
gclog_or_tty->print_cr("[GC concurrent-count-end, %1.7lf]",
count_end_sec - count_start_sec);
}
}
}
double end_time = os::elapsedVTime();
_vtime_count_accum += (end_time - counting_start_time);
// Update the total virtual time before doing this, since it will try
// to measure it to get the vtime for this marking. We purposely
// neglect the presumably-short "completeCleanup" phase here.
_vtime_accum = (end_time - _vtime_start);
if (!cm()->has_aborted()) {
if (g1_policy->adaptive_young_list_length()) {
double now = os::elapsedTime();
double cleanup_prediction_ms = g1_policy->predict_cleanup_time_ms();
jlong sleep_time_ms = mmu_tracker->when_ms(now, cleanup_prediction_ms);
os::sleep(current_thread, sleep_time_ms, false);
}
CMCleanUp cl_cl(_cm);
sprintf(verbose_str, "GC cleanup");
VM_CGC_Operation op(&cl_cl, verbose_str);
VMThread::execute(&op);
} else {
g1h->set_marking_complete();
}
// Check if cleanup set the free_regions_coming flag. If it
// hasn't, we can just skip the next step.
if (g1h->free_regions_coming()) {
// The following will finish freeing up any regions that we
// found to be empty during cleanup. We'll do this part
// without joining the suspendible set. If an evacuation pause
// takes places, then we would carry on freeing regions in
// case they are needed by the pause. If a Full GC takes
// places, it would wait for us to process the regions
// reclaimed by cleanup.
double cleanup_start_sec = os::elapsedTime();
if (PrintGC) {
gclog_or_tty->date_stamp(PrintGCDateStamps);
gclog_or_tty->stamp(PrintGCTimeStamps);
gclog_or_tty->print_cr("[GC concurrent-cleanup-start]");
}
// Now do the remainder of the cleanup operation.
_cm->completeCleanup();
// Notify anyone who's waiting that there are no more free
// regions coming. We have to do this before we join the STS,
// otherwise we might deadlock: a GC worker could be blocked
// waiting for the notification whereas this thread will be
// blocked for the pause to finish while it's trying to join
// the STS, which is conditional on the GC workers finishing.
g1h->reset_free_regions_coming();
_sts.join();
g1_policy->record_concurrent_mark_cleanup_completed();
_sts.leave();
double cleanup_end_sec = os::elapsedTime();
if (PrintGC) {
gclog_or_tty->date_stamp(PrintGCDateStamps);
gclog_or_tty->stamp(PrintGCTimeStamps);
gclog_or_tty->print_cr("[GC concurrent-cleanup-end, %1.7lf]",
cleanup_end_sec - cleanup_start_sec);
}
}
guarantee(cm()->cleanup_list_is_empty(),
"at this point there should be no regions on the cleanup list");
if (cm()->has_aborted()) {
if (PrintGC) {
gclog_or_tty->date_stamp(PrintGCDateStamps);
gclog_or_tty->stamp(PrintGCTimeStamps);
gclog_or_tty->print_cr("[GC concurrent-mark-abort]");
}
}
// we now want to allow clearing of the marking bitmap to be
// suspended by a collection pause.
_sts.join();
_cm->clearNextBitmap();
_sts.leave();
}
// Update the number of full collections that have been
// completed. This will also notify the FullGCCount_lock in case a
// Java thread is waiting for a full GC to happen (e.g., it
// called System.gc() with +ExplicitGCInvokesConcurrent).
_sts.join();
g1h->increment_full_collections_completed(true /* concurrent */);
_sts.leave();
}
assert(_should_terminate, "just checking");
terminate();
}
