8203394: Implementation of JEP 331: Low-Overhead Heap Profiling
Summary: Implement Low-Overhead Heap Profiling
Reviewed-by: eosterlund, gthornbr, rehn, sspitsyn, tschatzl
/*
* Copyright (c) 2001, 2018, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*
*/
#include "precompiled.hpp"
#include "classfile/systemDictionary.hpp"
#include "gc/shared/allocTracer.hpp"
#include "gc/shared/barrierSet.hpp"
#include "gc/shared/collectedHeap.hpp"
#include "gc/shared/collectedHeap.inline.hpp"
#include "gc/shared/gcLocker.inline.hpp"
#include "gc/shared/gcHeapSummary.hpp"
#include "gc/shared/gcTrace.hpp"
#include "gc/shared/gcTraceTime.inline.hpp"
#include "gc/shared/gcWhen.hpp"
#include "gc/shared/vmGCOperations.hpp"
#include "logging/log.hpp"
#include "memory/metaspace.hpp"
#include "memory/resourceArea.hpp"
#include "oops/instanceMirrorKlass.hpp"
#include "oops/oop.inline.hpp"
#include "runtime/handles.inline.hpp"
#include "runtime/init.hpp"
#include "runtime/thread.inline.hpp"
#include "runtime/threadSMR.hpp"
#include "runtime/vmThread.hpp"
#include "services/heapDumper.hpp"
#include "utilities/align.hpp"
class ClassLoaderData;
#ifdef ASSERT
int CollectedHeap::_fire_out_of_memory_count = 0;
#endif
size_t CollectedHeap::_filler_array_max_size = 0;
template <>
void EventLogBase<GCMessage>::print(outputStream* st, GCMessage& m) {
st->print_cr("GC heap %s", m.is_before ? "before" : "after");
st->print_raw(m);
}
void GCHeapLog::log_heap(CollectedHeap* heap, bool before) {
if (!should_log()) {
return;
}
double timestamp = fetch_timestamp();
MutexLockerEx ml(&_mutex, Mutex::_no_safepoint_check_flag);
int index = compute_log_index();
_records[index].thread = NULL; // Its the GC thread so it's not that interesting.
_records[index].timestamp = timestamp;
_records[index].data.is_before = before;
stringStream st(_records[index].data.buffer(), _records[index].data.size());
st.print_cr("{Heap %s GC invocations=%u (full %u):",
before ? "before" : "after",
heap->total_collections(),
heap->total_full_collections());
heap->print_on(&st);
st.print_cr("}");
}
VirtualSpaceSummary CollectedHeap::create_heap_space_summary() {
size_t capacity_in_words = capacity() / HeapWordSize;
return VirtualSpaceSummary(
reserved_region().start(), reserved_region().start() + capacity_in_words, reserved_region().end());
}
GCHeapSummary CollectedHeap::create_heap_summary() {
VirtualSpaceSummary heap_space = create_heap_space_summary();
return GCHeapSummary(heap_space, used());
}
MetaspaceSummary CollectedHeap::create_metaspace_summary() {
const MetaspaceSizes meta_space(
MetaspaceUtils::committed_bytes(),
MetaspaceUtils::used_bytes(),
MetaspaceUtils::reserved_bytes());
const MetaspaceSizes data_space(
MetaspaceUtils::committed_bytes(Metaspace::NonClassType),
MetaspaceUtils::used_bytes(Metaspace::NonClassType),
MetaspaceUtils::reserved_bytes(Metaspace::NonClassType));
const MetaspaceSizes class_space(
MetaspaceUtils::committed_bytes(Metaspace::ClassType),
MetaspaceUtils::used_bytes(Metaspace::ClassType),
MetaspaceUtils::reserved_bytes(Metaspace::ClassType));
const MetaspaceChunkFreeListSummary& ms_chunk_free_list_summary =
MetaspaceUtils::chunk_free_list_summary(Metaspace::NonClassType);
const MetaspaceChunkFreeListSummary& class_chunk_free_list_summary =
MetaspaceUtils::chunk_free_list_summary(Metaspace::ClassType);
return MetaspaceSummary(MetaspaceGC::capacity_until_GC(), meta_space, data_space, class_space,
ms_chunk_free_list_summary, class_chunk_free_list_summary);
}
void CollectedHeap::print_heap_before_gc() {
Universe::print_heap_before_gc();
if (_gc_heap_log != NULL) {
_gc_heap_log->log_heap_before(this);
}
}
void CollectedHeap::print_heap_after_gc() {
Universe::print_heap_after_gc();
if (_gc_heap_log != NULL) {
_gc_heap_log->log_heap_after(this);
}
}
void CollectedHeap::print_on_error(outputStream* st) const {
st->print_cr("Heap:");
print_extended_on(st);
st->cr();
BarrierSet::barrier_set()->print_on(st);
}
void CollectedHeap::trace_heap(GCWhen::Type when, const GCTracer* gc_tracer) {
const GCHeapSummary& heap_summary = create_heap_summary();
gc_tracer->report_gc_heap_summary(when, heap_summary);
const MetaspaceSummary& metaspace_summary = create_metaspace_summary();
gc_tracer->report_metaspace_summary(when, metaspace_summary);
}
void CollectedHeap::trace_heap_before_gc(const GCTracer* gc_tracer) {
trace_heap(GCWhen::BeforeGC, gc_tracer);
}
void CollectedHeap::trace_heap_after_gc(const GCTracer* gc_tracer) {
trace_heap(GCWhen::AfterGC, gc_tracer);
}
// WhiteBox API support for concurrent collectors. These are the
// default implementations, for collectors which don't support this
// feature.
bool CollectedHeap::supports_concurrent_phase_control() const {
return false;
}
const char* const* CollectedHeap::concurrent_phases() const {
static const char* const result[] = { NULL };
return result;
}
bool CollectedHeap::request_concurrent_phase(const char* phase) {
return false;
}
bool CollectedHeap::is_oop(oop object) const {
if (!check_obj_alignment(object)) {
return false;
}
if (!is_in_reserved(object)) {
return false;
}
if (is_in_reserved(object->klass_or_null())) {
return false;
}
return true;
}
// Memory state functions.
CollectedHeap::CollectedHeap() :
_is_gc_active(false),
_total_collections(0),
_total_full_collections(0),
_gc_cause(GCCause::_no_gc),
_gc_lastcause(GCCause::_no_gc)
{
const size_t max_len = size_t(arrayOopDesc::max_array_length(T_INT));
const size_t elements_per_word = HeapWordSize / sizeof(jint);
_filler_array_max_size = align_object_size(filler_array_hdr_size() +
max_len / elements_per_word);
NOT_PRODUCT(_promotion_failure_alot_count = 0;)
NOT_PRODUCT(_promotion_failure_alot_gc_number = 0;)
if (UsePerfData) {
EXCEPTION_MARK;
// create the gc cause jvmstat counters
_perf_gc_cause = PerfDataManager::create_string_variable(SUN_GC, "cause",
80, GCCause::to_string(_gc_cause), CHECK);
_perf_gc_lastcause =
PerfDataManager::create_string_variable(SUN_GC, "lastCause",
80, GCCause::to_string(_gc_lastcause), CHECK);
}
// Create the ring log
if (LogEvents) {
_gc_heap_log = new GCHeapLog();
} else {
_gc_heap_log = NULL;
}
}
// This interface assumes that it's being called by the
// vm thread. It collects the heap assuming that the
// heap lock is already held and that we are executing in
// the context of the vm thread.
void CollectedHeap::collect_as_vm_thread(GCCause::Cause cause) {
assert(Thread::current()->is_VM_thread(), "Precondition#1");
assert(Heap_lock->is_locked(), "Precondition#2");
GCCauseSetter gcs(this, cause);
switch (cause) {
case GCCause::_heap_inspection:
case GCCause::_heap_dump:
case GCCause::_metadata_GC_threshold : {
HandleMark hm;
do_full_collection(false); // don't clear all soft refs
break;
}
case GCCause::_metadata_GC_clear_soft_refs: {
HandleMark hm;
do_full_collection(true); // do clear all soft refs
break;
}
default:
ShouldNotReachHere(); // Unexpected use of this function
}
}
MetaWord* CollectedHeap::satisfy_failed_metadata_allocation(ClassLoaderData* loader_data,
size_t word_size,
Metaspace::MetadataType mdtype) {
uint loop_count = 0;
uint gc_count = 0;
uint full_gc_count = 0;
assert(!Heap_lock->owned_by_self(), "Should not be holding the Heap_lock");
do {
MetaWord* result = loader_data->metaspace_non_null()->allocate(word_size, mdtype);
if (result != NULL) {
return result;
}
if (GCLocker::is_active_and_needs_gc()) {
// If the GCLocker is active, just expand and allocate.
// If that does not succeed, wait if this thread is not
// in a critical section itself.
result = loader_data->metaspace_non_null()->expand_and_allocate(word_size, mdtype);
if (result != NULL) {
return result;
}
JavaThread* jthr = JavaThread::current();
if (!jthr->in_critical()) {
// Wait for JNI critical section to be exited
GCLocker::stall_until_clear();
// The GC invoked by the last thread leaving the critical
// section will be a young collection and a full collection
// is (currently) needed for unloading classes so continue
// to the next iteration to get a full GC.
continue;
} else {
if (CheckJNICalls) {
fatal("Possible deadlock due to allocating while"
" in jni critical section");
}
return NULL;
}
}
{ // Need lock to get self consistent gc_count's
MutexLocker ml(Heap_lock);
gc_count = Universe::heap()->total_collections();
full_gc_count = Universe::heap()->total_full_collections();
}
// Generate a VM operation
VM_CollectForMetadataAllocation op(loader_data,
word_size,
mdtype,
gc_count,
full_gc_count,
GCCause::_metadata_GC_threshold);
VMThread::execute(&op);
// If GC was locked out, try again. Check before checking success because the
// prologue could have succeeded and the GC still have been locked out.
if (op.gc_locked()) {
continue;
}
if (op.prologue_succeeded()) {
return op.result();
}
loop_count++;
if ((QueuedAllocationWarningCount > 0) &&
(loop_count % QueuedAllocationWarningCount == 0)) {
log_warning(gc, ergo)("satisfy_failed_metadata_allocation() retries %d times,"
" size=" SIZE_FORMAT, loop_count, word_size);
}
} while (true); // Until a GC is done
}
#ifndef PRODUCT
void CollectedHeap::check_for_bad_heap_word_value(HeapWord* addr, size_t size) {
if (CheckMemoryInitialization && ZapUnusedHeapArea) {
for (size_t slot = 0; slot < size; slot += 1) {
assert((*(intptr_t*) (addr + slot)) != ((intptr_t) badHeapWordVal),
"Found badHeapWordValue in post-allocation check");
}
}
}
void CollectedHeap::check_for_non_bad_heap_word_value(HeapWord* addr, size_t size) {
if (CheckMemoryInitialization && ZapUnusedHeapArea) {
for (size_t slot = 0; slot < size; slot += 1) {
assert((*(intptr_t*) (addr + slot)) == ((intptr_t) badHeapWordVal),
"Found non badHeapWordValue in pre-allocation check");
}
}
}
#endif // PRODUCT
#ifdef ASSERT
void CollectedHeap::check_for_valid_allocation_state() {
Thread *thread = Thread::current();
// How to choose between a pending exception and a potential
// OutOfMemoryError? Don't allow pending exceptions.
// This is a VM policy failure, so how do we exhaustively test it?
assert(!thread->has_pending_exception(),
"shouldn't be allocating with pending exception");
if (StrictSafepointChecks) {
assert(thread->allow_allocation(),
"Allocation done by thread for which allocation is blocked "
"by No_Allocation_Verifier!");
// Allocation of an oop can always invoke a safepoint,
// hence, the true argument
thread->check_for_valid_safepoint_state(true);
}
}
#endif
HeapWord* CollectedHeap::obj_allocate_raw(Klass* klass, size_t size,
bool* gc_overhead_limit_was_exceeded, TRAPS) {
if (UseTLAB) {
HeapWord* result = allocate_from_tlab(klass, size, THREAD);
if (result != NULL) {
return result;
}
}
return allocate_outside_tlab(klass, size, gc_overhead_limit_was_exceeded, THREAD);
}
HeapWord* CollectedHeap::allocate_from_tlab_slow(Klass* klass, size_t size, TRAPS) {
HeapWord* obj = NULL;
// In assertion mode, check that there was a sampling collector present
// in the stack. This enforces checking that no path is without a sampling
// collector.
// Only check if the sampler could actually sample something in this call path.
assert(!JvmtiExport::should_post_sampled_object_alloc()
|| !JvmtiSampledObjectAllocEventCollector::object_alloc_is_safe_to_sample()
|| THREAD->heap_sampler().sampling_collector_present(),
"Sampling collector not present.");
if (ThreadHeapSampler::enabled()) {
// Try to allocate the sampled object from TLAB, it is possible a sample
// point was put and the TLAB still has space.
obj = THREAD->tlab().allocate_sampled_object(size);
if (obj != NULL) {
return obj;
}
}
ThreadLocalAllocBuffer& tlab = THREAD->tlab();
// Retain tlab and allocate object in shared space if
// the amount free in the tlab is too large to discard.
if (tlab.free() > tlab.refill_waste_limit()) {
tlab.record_slow_allocation(size);
return NULL;
}
// Discard tlab and allocate a new one.
// To minimize fragmentation, the last TLAB may be smaller than the rest.
size_t new_tlab_size = tlab.compute_size(size);
tlab.clear_before_allocation();
if (new_tlab_size == 0) {
return NULL;
}
// Allocate a new TLAB requesting new_tlab_size. Any size
// between minimal and new_tlab_size is accepted.
size_t actual_tlab_size = 0;
size_t min_tlab_size = ThreadLocalAllocBuffer::compute_min_size(size);
obj = Universe::heap()->allocate_new_tlab(min_tlab_size, new_tlab_size, &actual_tlab_size);
if (obj == NULL) {
assert(actual_tlab_size == 0, "Allocation failed, but actual size was updated. min: " SIZE_FORMAT ", desired: " SIZE_FORMAT ", actual: " SIZE_FORMAT,
min_tlab_size, new_tlab_size, actual_tlab_size);
return NULL;
}
assert(actual_tlab_size != 0, "Allocation succeeded but actual size not updated. obj at: " PTR_FORMAT " min: " SIZE_FORMAT ", desired: " SIZE_FORMAT,
p2i(obj), min_tlab_size, new_tlab_size);
AllocTracer::send_allocation_in_new_tlab(klass, obj, actual_tlab_size * HeapWordSize, size * HeapWordSize, THREAD);
if (ZeroTLAB) {
// ..and clear it.
Copy::zero_to_words(obj, actual_tlab_size);
} else {
// ...and zap just allocated object.
#ifdef ASSERT
// Skip mangling the space corresponding to the object header to
// ensure that the returned space is not considered parsable by
// any concurrent GC thread.
size_t hdr_size = oopDesc::header_size();
Copy::fill_to_words(obj + hdr_size, actual_tlab_size - hdr_size, badHeapWordVal);
#endif // ASSERT
}
// Send the thread information about this allocation in case a sample is
// requested.
if (ThreadHeapSampler::enabled()) {
size_t tlab_bytes_since_last_sample = THREAD->tlab().bytes_since_last_sample_point();
THREAD->heap_sampler().check_for_sampling(obj, size, tlab_bytes_since_last_sample);
}
tlab.fill(obj, obj + size, actual_tlab_size);
return obj;
}
size_t CollectedHeap::max_tlab_size() const {
// TLABs can't be bigger than we can fill with a int[Integer.MAX_VALUE].
// This restriction could be removed by enabling filling with multiple arrays.
// If we compute that the reasonable way as
// header_size + ((sizeof(jint) * max_jint) / HeapWordSize)
// we'll overflow on the multiply, so we do the divide first.
// We actually lose a little by dividing first,
// but that just makes the TLAB somewhat smaller than the biggest array,
// which is fine, since we'll be able to fill that.
size_t max_int_size = typeArrayOopDesc::header_size(T_INT) +
sizeof(jint) *
((juint) max_jint / (size_t) HeapWordSize);
return align_down(max_int_size, MinObjAlignment);
}
size_t CollectedHeap::filler_array_hdr_size() {
return align_object_offset(arrayOopDesc::header_size(T_INT)); // align to Long
}
size_t CollectedHeap::filler_array_min_size() {
return align_object_size(filler_array_hdr_size()); // align to MinObjAlignment
}
#ifdef ASSERT
void CollectedHeap::fill_args_check(HeapWord* start, size_t words)
{
assert(words >= min_fill_size(), "too small to fill");
assert(is_object_aligned(words), "unaligned size");
assert(Universe::heap()->is_in_reserved(start), "not in heap");
assert(Universe::heap()->is_in_reserved(start + words - 1), "not in heap");
}
void CollectedHeap::zap_filler_array(HeapWord* start, size_t words, bool zap)
{
if (ZapFillerObjects && zap) {
Copy::fill_to_words(start + filler_array_hdr_size(),
words - filler_array_hdr_size(), 0XDEAFBABE);
}
}
#endif // ASSERT
void
CollectedHeap::fill_with_array(HeapWord* start, size_t words, bool zap)
{
assert(words >= filler_array_min_size(), "too small for an array");
assert(words <= filler_array_max_size(), "too big for a single object");
const size_t payload_size = words - filler_array_hdr_size();
const size_t len = payload_size * HeapWordSize / sizeof(jint);
assert((int)len >= 0, "size too large " SIZE_FORMAT " becomes %d", words, (int)len);
// Set the length first for concurrent GC.
((arrayOop)start)->set_length((int)len);
post_allocation_setup_common(Universe::intArrayKlassObj(), start);
DEBUG_ONLY(zap_filler_array(start, words, zap);)
}
void
CollectedHeap::fill_with_object_impl(HeapWord* start, size_t words, bool zap)
{
assert(words <= filler_array_max_size(), "too big for a single object");
if (words >= filler_array_min_size()) {
fill_with_array(start, words, zap);
} else if (words > 0) {
assert(words == min_fill_size(), "unaligned size");
post_allocation_setup_common(SystemDictionary::Object_klass(), start);
}
}
void CollectedHeap::fill_with_object(HeapWord* start, size_t words, bool zap)
{
DEBUG_ONLY(fill_args_check(start, words);)
HandleMark hm; // Free handles before leaving.
fill_with_object_impl(start, words, zap);
}
void CollectedHeap::fill_with_objects(HeapWord* start, size_t words, bool zap)
{
DEBUG_ONLY(fill_args_check(start, words);)
HandleMark hm; // Free handles before leaving.
// Multiple objects may be required depending on the filler array maximum size. Fill
// the range up to that with objects that are filler_array_max_size sized. The
// remainder is filled with a single object.
const size_t min = min_fill_size();
const size_t max = filler_array_max_size();
while (words > max) {
const size_t cur = (words - max) >= min ? max : max - min;
fill_with_array(start, cur, zap);
start += cur;
words -= cur;
}
fill_with_object_impl(start, words, zap);
}
void CollectedHeap::fill_with_dummy_object(HeapWord* start, HeapWord* end, bool zap) {
CollectedHeap::fill_with_object(start, end, zap);
}
HeapWord* CollectedHeap::allocate_new_tlab(size_t min_size,
size_t requested_size,
size_t* actual_size) {
guarantee(false, "thread-local allocation buffers not supported");
return NULL;
}
void CollectedHeap::ensure_parsability(bool retire_tlabs) {
// The second disjunct in the assertion below makes a concession
// for the start-up verification done while the VM is being
// created. Callers be careful that you know that mutators
// aren't going to interfere -- for instance, this is permissible
// if we are still single-threaded and have either not yet
// started allocating (nothing much to verify) or we have
// started allocating but are now a full-fledged JavaThread
// (and have thus made our TLAB's) available for filling.
assert(SafepointSynchronize::is_at_safepoint() ||
!is_init_completed(),
"Should only be called at a safepoint or at start-up"
" otherwise concurrent mutator activity may make heap "
" unparsable again");
const bool use_tlab = UseTLAB;
// The main thread starts allocating via a TLAB even before it
// has added itself to the threads list at vm boot-up.
JavaThreadIteratorWithHandle jtiwh;
assert(!use_tlab || jtiwh.length() > 0,
"Attempt to fill tlabs before main thread has been added"
" to threads list is doomed to failure!");
BarrierSet *bs = BarrierSet::barrier_set();
for (; JavaThread *thread = jtiwh.next(); ) {
if (use_tlab) thread->tlab().make_parsable(retire_tlabs);
bs->make_parsable(thread);
}
}
void CollectedHeap::accumulate_statistics_all_tlabs() {
if (UseTLAB) {
assert(SafepointSynchronize::is_at_safepoint() ||
!is_init_completed(),
"should only accumulate statistics on tlabs at safepoint");
ThreadLocalAllocBuffer::accumulate_statistics_before_gc();
}
}
void CollectedHeap::resize_all_tlabs() {
if (UseTLAB) {
assert(SafepointSynchronize::is_at_safepoint() ||
!is_init_completed(),
"should only resize tlabs at safepoint");
ThreadLocalAllocBuffer::resize_all_tlabs();
}
}
void CollectedHeap::full_gc_dump(GCTimer* timer, bool before) {
assert(timer != NULL, "timer is null");
if ((HeapDumpBeforeFullGC && before) || (HeapDumpAfterFullGC && !before)) {
GCTraceTime(Info, gc) tm(before ? "Heap Dump (before full gc)" : "Heap Dump (after full gc)", timer);
HeapDumper::dump_heap();
}
LogTarget(Trace, gc, classhisto) lt;
if (lt.is_enabled()) {
GCTraceTime(Trace, gc, classhisto) tm(before ? "Class Histogram (before full gc)" : "Class Histogram (after full gc)", timer);
ResourceMark rm;
LogStream ls(lt);
VM_GC_HeapInspection inspector(&ls, false /* ! full gc */);
inspector.doit();
}
}
void CollectedHeap::pre_full_gc_dump(GCTimer* timer) {
full_gc_dump(timer, true);
}
void CollectedHeap::post_full_gc_dump(GCTimer* timer) {
full_gc_dump(timer, false);
}
void CollectedHeap::initialize_reserved_region(HeapWord *start, HeapWord *end) {
// It is important to do this in a way such that concurrent readers can't
// temporarily think something is in the heap. (Seen this happen in asserts.)
_reserved.set_word_size(0);
_reserved.set_start(start);
_reserved.set_end(end);
}
void CollectedHeap::post_initialize() {
initialize_serviceability();
}
#ifndef PRODUCT
bool CollectedHeap::promotion_should_fail(volatile size_t* count) {
// Access to count is not atomic; the value does not have to be exact.
if (PromotionFailureALot) {
const size_t gc_num = total_collections();
const size_t elapsed_gcs = gc_num - _promotion_failure_alot_gc_number;
if (elapsed_gcs >= PromotionFailureALotInterval) {
// Test for unsigned arithmetic wrap-around.
if (++*count >= PromotionFailureALotCount) {
*count = 0;
return true;
}
}
}
return false;
}
bool CollectedHeap::promotion_should_fail() {
return promotion_should_fail(&_promotion_failure_alot_count);
}
void CollectedHeap::reset_promotion_should_fail(volatile size_t* count) {
if (PromotionFailureALot) {
_promotion_failure_alot_gc_number = total_collections();
*count = 0;
}
}
void CollectedHeap::reset_promotion_should_fail() {
reset_promotion_should_fail(&_promotion_failure_alot_count);
}
#endif // #ifndef PRODUCT
bool CollectedHeap::supports_object_pinning() const {
return false;
}
oop CollectedHeap::pin_object(JavaThread* thread, oop obj) {
ShouldNotReachHere();
return NULL;
}
void CollectedHeap::unpin_object(JavaThread* thread, oop obj) {
ShouldNotReachHere();
}
void CollectedHeap::deduplicate_string(oop str) {
// Do nothing, unless overridden in subclass.
}