/* * Copyright (c) 2001, 2025, 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 "gc/serial/cardTableRS.hpp" #include "gc/serial/serialGcRefProcProxyTask.hpp" #include "gc/serial/serialHeap.inline.hpp" #include "gc/serial/serialStringDedup.inline.hpp" #include "gc/serial/tenuredGeneration.hpp" #include "gc/shared/adaptiveSizePolicy.hpp" #include "gc/shared/ageTable.inline.hpp" #include "gc/shared/collectorCounters.hpp" #include "gc/shared/continuationGCSupport.inline.hpp" #include "gc/shared/gcArguments.hpp" #include "gc/shared/gcHeapSummary.hpp" #include "gc/shared/gcLocker.hpp" #include "gc/shared/gcPolicyCounters.hpp" #include "gc/shared/gcTimer.hpp" #include "gc/shared/gcTrace.hpp" #include "gc/shared/gcTraceTime.inline.hpp" #include "gc/shared/referencePolicy.hpp" #include "gc/shared/referenceProcessorPhaseTimes.hpp" #include "gc/shared/space.hpp" #include "gc/shared/spaceDecorator.hpp" #include "gc/shared/strongRootsScope.hpp" #include "gc/shared/weakProcessor.hpp" #include "logging/log.hpp" #include "memory/iterator.inline.hpp" #include "memory/reservedSpace.hpp" #include "memory/resourceArea.hpp" #include "oops/instanceRefKlass.hpp" #include "oops/oop.inline.hpp" #include "runtime/java.hpp" #include "runtime/javaThread.hpp" #include "runtime/prefetch.inline.hpp" #include "runtime/threads.hpp" #include "utilities/align.hpp" #include "utilities/copy.hpp" #include "utilities/globalDefinitions.hpp" #include "utilities/stack.inline.hpp" class PromoteFailureClosure : public InHeapScanClosure { template void do_oop_work(T* p) { assert(is_in_young_gen(p), "promote-fail objs must be in young-gen"); assert(!SerialHeap::heap()->young_gen()->to()->is_in_reserved(p), "must not be in to-space"); try_scavenge(p, [] (auto) {}); } public: PromoteFailureClosure(DefNewGeneration* g) : InHeapScanClosure(g) {} void do_oop(oop* p) { do_oop_work(p); } void do_oop(narrowOop* p) { do_oop_work(p); } }; class RootScanClosure : public OffHeapScanClosure { template void do_oop_work(T* p) { assert(!SerialHeap::heap()->is_in_reserved(p), "outside the heap"); try_scavenge(p, [] (auto) {}); } public: RootScanClosure(DefNewGeneration* g) : OffHeapScanClosure(g) {} void do_oop(oop* p) { do_oop_work(p); } void do_oop(narrowOop* p) { do_oop_work(p); } }; class CLDScanClosure: public CLDClosure { class CLDOopClosure : public OffHeapScanClosure { ClassLoaderData* _scanned_cld; template void do_oop_work(T* p) { assert(!SerialHeap::heap()->is_in_reserved(p), "outside the heap"); try_scavenge(p, [&] (oop new_obj) { assert(_scanned_cld != nullptr, "inv"); if (is_in_young_gen(new_obj) && !_scanned_cld->has_modified_oops()) { _scanned_cld->record_modified_oops(); } }); } public: CLDOopClosure(DefNewGeneration* g) : OffHeapScanClosure(g), _scanned_cld(nullptr) {} void set_scanned_cld(ClassLoaderData* cld) { assert(cld == nullptr || _scanned_cld == nullptr, "Must be"); _scanned_cld = cld; } void do_oop(oop* p) { do_oop_work(p); } void do_oop(narrowOop* p) { ShouldNotReachHere(); } }; CLDOopClosure _oop_closure; public: CLDScanClosure(DefNewGeneration* g) : _oop_closure(g) {} void do_cld(ClassLoaderData* cld) { // If the cld has not been dirtied we know that there's // no references into the young gen and we can skip it. if (cld->has_modified_oops()) { // Tell the closure which CLD is being scanned so that it can be dirtied // if oops are left pointing into the young gen. _oop_closure.set_scanned_cld(cld); // Clean the cld since we're going to scavenge all the metadata. cld->oops_do(&_oop_closure, ClassLoaderData::_claim_none, /*clear_modified_oops*/true); _oop_closure.set_scanned_cld(nullptr); } } }; class IsAliveClosure: public BoolObjectClosure { HeapWord* _young_gen_end; public: IsAliveClosure(DefNewGeneration* g): _young_gen_end(g->reserved().end()) {} bool do_object_b(oop p) { return cast_from_oop(p) >= _young_gen_end || p->is_forwarded(); } }; class AdjustWeakRootClosure: public OffHeapScanClosure { template void do_oop_work(T* p) { DEBUG_ONLY(SerialHeap* heap = SerialHeap::heap();) assert(!heap->is_in_reserved(p), "outside the heap"); oop obj = RawAccess::oop_load(p); if (is_in_young_gen(obj)) { assert(!heap->young_gen()->to()->is_in_reserved(obj), "inv"); assert(obj->is_forwarded(), "forwarded before weak-root-processing"); oop new_obj = obj->forwardee(); RawAccess::oop_store(p, new_obj); } } public: AdjustWeakRootClosure(DefNewGeneration* g): OffHeapScanClosure(g) {} void do_oop(oop* p) { do_oop_work(p); } void do_oop(narrowOop* p) { ShouldNotReachHere(); } }; class KeepAliveClosure: public OopClosure { DefNewGeneration* _young_gen; HeapWord* _young_gen_end; CardTableRS* _rs; bool is_in_young_gen(void* p) const { return p < _young_gen_end; } template void do_oop_work(T* p) { oop obj = RawAccess::oop_load(p); if (is_in_young_gen(obj)) { oop new_obj = obj->is_forwarded() ? obj->forwardee() : _young_gen->copy_to_survivor_space(obj); RawAccess::oop_store(p, new_obj); if (is_in_young_gen(new_obj) && !is_in_young_gen(p)) { _rs->inline_write_ref_field_gc(p); } } } public: KeepAliveClosure(DefNewGeneration* g) : _young_gen(g), _young_gen_end(g->reserved().end()), _rs(SerialHeap::heap()->rem_set()) {} void do_oop(oop* p) { do_oop_work(p); } void do_oop(narrowOop* p) { do_oop_work(p); } }; class FastEvacuateFollowersClosure: public VoidClosure { SerialHeap* _heap; YoungGenScanClosure* _young_cl; OldGenScanClosure* _old_cl; public: FastEvacuateFollowersClosure(SerialHeap* heap, YoungGenScanClosure* young_cl, OldGenScanClosure* old_cl) : _heap(heap), _young_cl(young_cl), _old_cl(old_cl) {} void do_void() { _heap->scan_evacuated_objs(_young_cl, _old_cl); } }; DefNewGeneration::DefNewGeneration(ReservedSpace rs, size_t initial_size, size_t min_size, size_t max_size, const char* policy) : Generation(rs, initial_size), _promotion_failed(false), _promo_failure_drain_in_progress(false), _string_dedup_requests() { MemRegion cmr((HeapWord*)_virtual_space.low(), (HeapWord*)_virtual_space.high()); SerialHeap* gch = SerialHeap::heap(); gch->rem_set()->resize_covered_region(cmr); _eden_space = new ContiguousSpace(); _from_space = new ContiguousSpace(); _to_space = new ContiguousSpace(); // Compute the maximum eden and survivor space sizes. These sizes // are computed assuming the entire reserved space is committed. // These values are exported as performance counters. uintx size = _virtual_space.reserved_size(); _max_survivor_size = compute_survivor_size(size, SpaceAlignment); _max_eden_size = size - (2*_max_survivor_size); // allocate the performance counters // Generation counters -- generation 0, 3 subspaces _gen_counters = new GenerationCounters("new", 0, 3, min_size, max_size, _virtual_space.committed_size()); _gc_counters = new CollectorCounters(policy, 0); _eden_counters = new CSpaceCounters("eden", 0, _max_eden_size, _eden_space, _gen_counters); _from_counters = new CSpaceCounters("s0", 1, _max_survivor_size, _from_space, _gen_counters); _to_counters = new CSpaceCounters("s1", 2, _max_survivor_size, _to_space, _gen_counters); compute_space_boundaries(0, SpaceDecorator::Clear, SpaceDecorator::Mangle); update_counters(); _old_gen = nullptr; _tenuring_threshold = MaxTenuringThreshold; _pretenure_size_threshold_words = PretenureSizeThreshold >> LogHeapWordSize; _ref_processor = nullptr; _gc_timer = new STWGCTimer(); _gc_tracer = new DefNewTracer(); } void DefNewGeneration::compute_space_boundaries(uintx minimum_eden_size, bool clear_space, bool mangle_space) { // If the spaces are being cleared (only done at heap initialization // currently), the survivor spaces need not be empty. // Otherwise, no care is taken for used areas in the survivor spaces // so check. assert(clear_space || (to()->is_empty() && from()->is_empty()), "Initialization of the survivor spaces assumes these are empty"); // Compute sizes uintx size = _virtual_space.committed_size(); uintx survivor_size = compute_survivor_size(size, SpaceAlignment); uintx eden_size = size - (2*survivor_size); if (eden_size > max_eden_size()) { // Need to reduce eden_size to satisfy the max constraint. The delta needs // to be 2*SpaceAlignment aligned so that both survivors are properly // aligned. uintx eden_delta = align_up(eden_size - max_eden_size(), 2*SpaceAlignment); eden_size -= eden_delta; survivor_size += eden_delta/2; } assert(eden_size > 0 && survivor_size <= eden_size, "just checking"); if (eden_size < minimum_eden_size) { // May happen due to 64Kb rounding, if so adjust eden size back up minimum_eden_size = align_up(minimum_eden_size, SpaceAlignment); uintx maximum_survivor_size = (size - minimum_eden_size) / 2; uintx unaligned_survivor_size = align_down(maximum_survivor_size, SpaceAlignment); survivor_size = MAX2(unaligned_survivor_size, SpaceAlignment); eden_size = size - (2*survivor_size); assert(eden_size > 0 && survivor_size <= eden_size, "just checking"); assert(eden_size >= minimum_eden_size, "just checking"); } char *eden_start = _virtual_space.low(); char *from_start = eden_start + eden_size; char *to_start = from_start + survivor_size; char *to_end = to_start + survivor_size; assert(to_end == _virtual_space.high(), "just checking"); assert(is_aligned(eden_start, SpaceAlignment), "checking alignment"); assert(is_aligned(from_start, SpaceAlignment), "checking alignment"); assert(is_aligned(to_start, SpaceAlignment), "checking alignment"); MemRegion edenMR((HeapWord*)eden_start, (HeapWord*)from_start); MemRegion fromMR((HeapWord*)from_start, (HeapWord*)to_start); MemRegion toMR ((HeapWord*)to_start, (HeapWord*)to_end); // A minimum eden size implies that there is a part of eden that // is being used and that affects the initialization of any // newly formed eden. bool live_in_eden = minimum_eden_size > 0; // Reset the spaces for their new regions. eden()->initialize(edenMR, clear_space && !live_in_eden, SpaceDecorator::Mangle); // If clear_space and live_in_eden, we will not have cleared any // portion of eden above its top. This can cause newly // expanded space not to be mangled if using ZapUnusedHeapArea. // We explicitly do such mangling here. if (ZapUnusedHeapArea && clear_space && live_in_eden && mangle_space) { eden()->mangle_unused_area(); } from()->initialize(fromMR, clear_space, mangle_space); to()->initialize(toMR, clear_space, mangle_space); } void DefNewGeneration::swap_spaces() { ContiguousSpace* s = from(); _from_space = to(); _to_space = s; if (UsePerfData) { CSpaceCounters* c = _from_counters; _from_counters = _to_counters; _to_counters = c; } } bool DefNewGeneration::expand(size_t bytes) { HeapWord* prev_high = (HeapWord*) _virtual_space.high(); bool success = _virtual_space.expand_by(bytes); if (success && ZapUnusedHeapArea) { // Mangle newly committed space immediately because it // can be done here more simply that after the new // spaces have been computed. HeapWord* new_high = (HeapWord*) _virtual_space.high(); MemRegion mangle_region(prev_high, new_high); SpaceMangler::mangle_region(mangle_region); } return success; } size_t DefNewGeneration::calculate_thread_increase_size(int threads_count) const { size_t thread_increase_size = 0; // Check an overflow at 'threads_count * NewSizeThreadIncrease'. if (threads_count > 0 && NewSizeThreadIncrease <= max_uintx / threads_count) { thread_increase_size = threads_count * NewSizeThreadIncrease; } return thread_increase_size; } size_t DefNewGeneration::adjust_for_thread_increase(size_t new_size_candidate, size_t new_size_before, size_t alignment, size_t thread_increase_size) const { size_t desired_new_size = new_size_before; if (NewSizeThreadIncrease > 0 && thread_increase_size > 0) { // 1. Check an overflow at 'new_size_candidate + thread_increase_size'. if (new_size_candidate <= max_uintx - thread_increase_size) { new_size_candidate += thread_increase_size; // 2. Check an overflow at 'align_up'. size_t aligned_max = ((max_uintx - alignment) & ~(alignment-1)); if (new_size_candidate <= aligned_max) { desired_new_size = align_up(new_size_candidate, alignment); } } } return desired_new_size; } void DefNewGeneration::compute_new_size() { // This is called after a GC that includes the old generation, so from-space // will normally be empty. // Note that we check both spaces, since if scavenge failed they revert roles. // If not we bail out (otherwise we would have to relocate the objects). if (!from()->is_empty() || !to()->is_empty()) { return; } SerialHeap* gch = SerialHeap::heap(); size_t old_size = gch->old_gen()->capacity(); size_t new_size_before = _virtual_space.committed_size(); size_t min_new_size = NewSize; size_t max_new_size = reserved().byte_size(); assert(min_new_size <= new_size_before && new_size_before <= max_new_size, "just checking"); // All space sizes must be multiples of Generation::GenGrain. size_t alignment = Generation::GenGrain; int threads_count = Threads::number_of_non_daemon_threads(); size_t thread_increase_size = calculate_thread_increase_size(threads_count); size_t new_size_candidate = old_size / NewRatio; // Compute desired new generation size based on NewRatio and NewSizeThreadIncrease // and reverts to previous value if any overflow happens size_t desired_new_size = adjust_for_thread_increase(new_size_candidate, new_size_before, alignment, thread_increase_size); // Adjust new generation size desired_new_size = clamp(desired_new_size, min_new_size, max_new_size); assert(desired_new_size <= max_new_size, "just checking"); bool changed = false; if (desired_new_size > new_size_before) { size_t change = desired_new_size - new_size_before; assert(change % alignment == 0, "just checking"); if (expand(change)) { changed = true; } // If the heap failed to expand to the desired size, // "changed" will be false. If the expansion failed // (and at this point it was expected to succeed), // ignore the failure (leaving "changed" as false). } if (desired_new_size < new_size_before && eden()->is_empty()) { // bail out of shrinking if objects in eden size_t change = new_size_before - desired_new_size; assert(change % alignment == 0, "just checking"); _virtual_space.shrink_by(change); changed = true; } if (changed) { // The spaces have already been mangled at this point but // may not have been cleared (set top = bottom) and should be. // Mangling was done when the heap was being expanded. compute_space_boundaries(eden()->used(), SpaceDecorator::Clear, SpaceDecorator::DontMangle); MemRegion cmr((HeapWord*)_virtual_space.low(), (HeapWord*)_virtual_space.high()); gch->rem_set()->resize_covered_region(cmr); log_debug(gc, ergo, heap)( "New generation size %zuK->%zuK [eden=%zuK,survivor=%zuK]", new_size_before/K, _virtual_space.committed_size()/K, eden()->capacity()/K, from()->capacity()/K); log_trace(gc, ergo, heap)( " [allowed %zuK extra for %d threads]", thread_increase_size/K, threads_count); } } void DefNewGeneration::ref_processor_init() { assert(_ref_processor == nullptr, "a reference processor already exists"); assert(!_reserved.is_empty(), "empty generation?"); _span_based_discoverer.set_span(_reserved); _ref_processor = new ReferenceProcessor(&_span_based_discoverer); // a vanilla reference processor } size_t DefNewGeneration::capacity() const { return eden()->capacity() + from()->capacity(); // to() is only used during scavenge } size_t DefNewGeneration::used() const { return eden()->used() + from()->used(); // to() is only used during scavenge } size_t DefNewGeneration::free() const { return eden()->free() + from()->free(); // to() is only used during scavenge } size_t DefNewGeneration::max_capacity() const { const size_t reserved_bytes = reserved().byte_size(); return reserved_bytes - compute_survivor_size(reserved_bytes, SpaceAlignment); } bool DefNewGeneration::is_in(const void* p) const { return eden()->is_in(p) || from()->is_in(p) || to() ->is_in(p); } size_t DefNewGeneration::unsafe_max_alloc_nogc() const { return eden()->free(); } size_t DefNewGeneration::capacity_before_gc() const { return eden()->capacity(); } void DefNewGeneration::object_iterate(ObjectClosure* blk) { eden()->object_iterate(blk); from()->object_iterate(blk); } // If "p" is in the space, returns the address of the start of the // "block" that contains "p". We say "block" instead of "object" since // some heaps may not pack objects densely; a chunk may either be an // object or a non-object. If "p" is not in the space, return null. // Very general, slow implementation. static HeapWord* block_start_const(const ContiguousSpace* cs, const void* p) { assert(MemRegion(cs->bottom(), cs->end()).contains(p), "p (" PTR_FORMAT ") not in space [" PTR_FORMAT ", " PTR_FORMAT ")", p2i(p), p2i(cs->bottom()), p2i(cs->end())); if (p >= cs->top()) { return cs->top(); } else { HeapWord* last = cs->bottom(); HeapWord* cur = last; while (cur <= p) { last = cur; cur += cast_to_oop(cur)->size(); } assert(oopDesc::is_oop(cast_to_oop(last)), PTR_FORMAT " should be an object start", p2i(last)); return last; } } HeapWord* DefNewGeneration::block_start(const void* p) const { if (eden()->is_in_reserved(p)) { return block_start_const(eden(), p); } if (from()->is_in_reserved(p)) { return block_start_const(from(), p); } assert(to()->is_in_reserved(p), "inv"); return block_start_const(to(), p); } void DefNewGeneration::adjust_desired_tenuring_threshold() { // Set the desired survivor size to half the real survivor space size_t const survivor_capacity = to()->capacity() / HeapWordSize; size_t const desired_survivor_size = (size_t)((((double)survivor_capacity) * TargetSurvivorRatio) / 100); _tenuring_threshold = age_table()->compute_tenuring_threshold(desired_survivor_size); if (UsePerfData) { GCPolicyCounters* gc_counters = SerialHeap::heap()->counters(); gc_counters->tenuring_threshold()->set_value(_tenuring_threshold); gc_counters->desired_survivor_size()->set_value(desired_survivor_size * oopSize); } age_table()->print_age_table(); } bool DefNewGeneration::collect(bool clear_all_soft_refs) { SerialHeap* heap = SerialHeap::heap(); assert(to()->is_empty(), "Else not collection_attempt_is_safe"); _gc_timer->register_gc_start(); _gc_tracer->report_gc_start(heap->gc_cause(), _gc_timer->gc_start()); _ref_processor->start_discovery(clear_all_soft_refs); _old_gen = heap->old_gen(); init_assuming_no_promotion_failure(); GCTraceTime(Trace, gc, phases) tm("DefNew", nullptr, heap->gc_cause()); heap->trace_heap_before_gc(_gc_tracer); // These can be shared for all code paths IsAliveClosure is_alive(this); age_table()->clear(); to()->clear(SpaceDecorator::Mangle); YoungGenScanClosure young_gen_cl(this); OldGenScanClosure old_gen_cl(this); FastEvacuateFollowersClosure evacuate_followers(heap, &young_gen_cl, &old_gen_cl); { StrongRootsScope srs(0); RootScanClosure root_cl{this}; CLDScanClosure cld_cl{this}; MarkingNMethodClosure code_cl(&root_cl, NMethodToOopClosure::FixRelocations, false /* keepalive_nmethods */); HeapWord* saved_top_in_old_gen = _old_gen->space()->top(); heap->process_roots(SerialHeap::SO_ScavengeCodeCache, &root_cl, &cld_cl, &cld_cl, &code_cl); _old_gen->scan_old_to_young_refs(saved_top_in_old_gen); } // "evacuate followers". evacuate_followers.do_void(); { // Reference processing KeepAliveClosure keep_alive(this); ReferenceProcessor* rp = ref_processor(); ReferenceProcessorPhaseTimes pt(_gc_timer, rp->max_num_queues()); SerialGCRefProcProxyTask task(is_alive, keep_alive, evacuate_followers); const ReferenceProcessorStats& stats = rp->process_discovered_references(task, pt); _gc_tracer->report_gc_reference_stats(stats); _gc_tracer->report_tenuring_threshold(tenuring_threshold()); pt.print_all_references(); } { AdjustWeakRootClosure cl{this}; WeakProcessor::weak_oops_do(&is_alive, &cl); } _string_dedup_requests.flush(); if (!_promotion_failed) { // Swap the survivor spaces. eden()->clear(SpaceDecorator::Mangle); from()->clear(SpaceDecorator::Mangle); swap_spaces(); assert(to()->is_empty(), "to space should be empty now"); adjust_desired_tenuring_threshold(); } else { assert(_promo_failure_scan_stack.is_empty(), "post condition"); _promo_failure_scan_stack.clear(true); // Clear cached segments. remove_forwarding_pointers(); log_info(gc, promotion)("Promotion failed"); _gc_tracer->report_promotion_failed(_promotion_failed_info); // Reset the PromotionFailureALot counters. NOT_PRODUCT(heap->reset_promotion_should_fail();) } heap->trace_heap_after_gc(_gc_tracer); _gc_timer->register_gc_end(); _gc_tracer->report_gc_end(_gc_timer->gc_end(), _gc_timer->time_partitions()); return !_promotion_failed; } void DefNewGeneration::init_assuming_no_promotion_failure() { _promotion_failed = false; _promotion_failed_info.reset(); } void DefNewGeneration::remove_forwarding_pointers() { assert(_promotion_failed, "precondition"); // Will enter Full GC soon due to failed promotion. Must reset the mark word // of objs in young-gen so that no objs are marked (forwarded) when Full GC // starts. (The mark word is overloaded: `is_marked()` == `is_forwarded()`.) struct ResetForwardedMarkWord : ObjectClosure { void do_object(oop obj) override { if (obj->is_self_forwarded()) { obj->unset_self_forwarded(); } else if (obj->is_forwarded()) { // To restore the klass-bits in the header. // Needed for object iteration to work properly. obj->set_mark(obj->forwardee()->prototype_mark()); } } } cl; eden()->object_iterate(&cl); from()->object_iterate(&cl); } void DefNewGeneration::handle_promotion_failure(oop old) { log_debug(gc, promotion)("Promotion failure size = %zu) ", old->size()); _promotion_failed = true; _promotion_failed_info.register_copy_failure(old->size()); ContinuationGCSupport::transform_stack_chunk(old); // forward to self old->forward_to_self(); _promo_failure_scan_stack.push(old); if (!_promo_failure_drain_in_progress) { // prevent recursion in copy_to_survivor_space() _promo_failure_drain_in_progress = true; drain_promo_failure_scan_stack(); _promo_failure_drain_in_progress = false; } } oop DefNewGeneration::copy_to_survivor_space(oop old) { assert(is_in_reserved(old) && !old->is_forwarded(), "shouldn't be scavenging this oop"); size_t s = old->size(); oop obj = nullptr; // Try allocating obj in to-space (unless too old) if (old->age() < tenuring_threshold()) { obj = cast_to_oop(to()->allocate(s)); } bool new_obj_is_tenured = false; // Otherwise try allocating obj tenured if (obj == nullptr) { obj = _old_gen->allocate_for_promotion(old, s); if (obj == nullptr) { handle_promotion_failure(old); return old; } new_obj_is_tenured = true; } // Prefetch beyond obj const intx interval = PrefetchCopyIntervalInBytes; Prefetch::write(obj, interval); // Copy obj Copy::aligned_disjoint_words(cast_from_oop(old), cast_from_oop(obj), s); ContinuationGCSupport::transform_stack_chunk(obj); if (!new_obj_is_tenured) { // Increment age if obj still in new generation obj->incr_age(); age_table()->add(obj, s); } // Done, insert forward pointer to obj in this header old->forward_to(obj); if (SerialStringDedup::is_candidate_from_evacuation(obj, new_obj_is_tenured)) { // Record old; request adds a new weak reference, which reference // processing expects to refer to a from-space object. _string_dedup_requests.add(old); } return obj; } void DefNewGeneration::drain_promo_failure_scan_stack() { PromoteFailureClosure cl{this}; while (!_promo_failure_scan_stack.is_empty()) { oop obj = _promo_failure_scan_stack.pop(); obj->oop_iterate(&cl); } } void DefNewGeneration::contribute_scratch(void*& scratch, size_t& num_words) { if (_promotion_failed) { return; } const size_t MinFreeScratchWords = 100; ContiguousSpace* to_space = to(); const size_t free_words = pointer_delta(to_space->end(), to_space->top()); if (free_words >= MinFreeScratchWords) { scratch = to_space->top(); num_words = free_words; } } void DefNewGeneration::reset_scratch() { // If contributing scratch in to_space, mangle all of // to_space if ZapUnusedHeapArea. This is needed because // top is not maintained while using to-space as scratch. if (ZapUnusedHeapArea) { to()->mangle_unused_area(); } } void DefNewGeneration::gc_epilogue(bool full) { assert(!GCLocker::is_active(), "We should not be executing here"); // update the generation and space performance counters update_counters(); } void DefNewGeneration::update_counters() { if (UsePerfData) { _eden_counters->update_all(); _from_counters->update_all(); _to_counters->update_all(); _gen_counters->update_all(_virtual_space.committed_size()); } } void DefNewGeneration::verify() { eden()->verify(); from()->verify(); to()->verify(); } void DefNewGeneration::print_on(outputStream* st) const { st->print("%-10s", name()); st->print(" total %zuK, used %zuK ", capacity() / K, used() / K); _virtual_space.print_space_boundaries_on(st); StreamIndentor si(st, 1); eden()->print_on(st, "eden "); from()->print_on(st, "from "); to()->print_on(st, "to "); } HeapWord* DefNewGeneration::allocate(size_t word_size) { // This is the slow-path allocation for the DefNewGeneration. // Most allocations are fast-path in compiled code. // We try to allocate from the eden. If that works, we are happy. // Note that since DefNewGeneration supports lock-free allocation, we // have to use it here, as well. HeapWord* result = eden()->par_allocate(word_size); return result; } HeapWord* DefNewGeneration::par_allocate(size_t word_size) { return eden()->par_allocate(word_size); } size_t DefNewGeneration::tlab_capacity() const { return eden()->capacity(); } size_t DefNewGeneration::tlab_used() const { return eden()->used(); } size_t DefNewGeneration::unsafe_max_tlab_alloc() const { return unsafe_max_alloc_nogc(); }