g1CollectedHeap.hpp 75.4 KB
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/*
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 * Copyright (c) 2001, 2014, Oracle and/or its affiliates. All rights reserved.
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 * 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.
 *
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 * 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.
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 *
 */

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#ifndef SHARE_VM_GC_IMPLEMENTATION_G1_G1COLLECTEDHEAP_HPP
#define SHARE_VM_GC_IMPLEMENTATION_G1_G1COLLECTEDHEAP_HPP

#include "gc_implementation/g1/concurrentMark.hpp"
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#include "gc_implementation/g1/evacuationInfo.hpp"
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#include "gc_implementation/g1/g1AllocRegion.hpp"
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#include "gc_implementation/g1/g1HRPrinter.hpp"
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#include "gc_implementation/g1/g1MonitoringSupport.hpp"
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#include "gc_implementation/g1/g1RemSet.hpp"
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#include "gc_implementation/g1/g1SATBCardTableModRefBS.hpp"
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#include "gc_implementation/g1/g1YCTypes.hpp"
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#include "gc_implementation/g1/heapRegionSeq.hpp"
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#include "gc_implementation/g1/heapRegionSet.hpp"
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#include "gc_implementation/shared/hSpaceCounters.hpp"
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#include "gc_implementation/shared/parGCAllocBuffer.hpp"
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#include "memory/barrierSet.hpp"
#include "memory/memRegion.hpp"
#include "memory/sharedHeap.hpp"
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#include "utilities/stack.hpp"
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// A "G1CollectedHeap" is an implementation of a java heap for HotSpot.
// It uses the "Garbage First" heap organization and algorithm, which
// may combine concurrent marking with parallel, incremental compaction of
// heap subsets that will yield large amounts of garbage.

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// Forward declarations
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class HeapRegion;
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class HRRSCleanupTask;
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class GenerationSpec;
class OopsInHeapRegionClosure;
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class G1KlassScanClosure;
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class G1ScanHeapEvacClosure;
class ObjectClosure;
class SpaceClosure;
class CompactibleSpaceClosure;
class Space;
class G1CollectorPolicy;
class GenRemSet;
class G1RemSet;
class HeapRegionRemSetIterator;
class ConcurrentMark;
class ConcurrentMarkThread;
class ConcurrentG1Refine;
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class ConcurrentGCTimer;
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class GenerationCounters;
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class STWGCTimer;
class G1NewTracer;
class G1OldTracer;
class EvacuationFailedInfo;
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class nmethod;
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class Ticks;
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typedef OverflowTaskQueue<StarTask, mtGC>         RefToScanQueue;
typedef GenericTaskQueueSet<RefToScanQueue, mtGC> RefToScanQueueSet;
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typedef int RegionIdx_t;   // needs to hold [ 0..max_regions() )
typedef int CardIdx_t;     // needs to hold [ 0..CardsPerRegion )

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enum GCAllocPurpose {
  GCAllocForTenured,
  GCAllocForSurvived,
  GCAllocPurposeCount
};

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class YoungList : public CHeapObj<mtGC> {
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private:
  G1CollectedHeap* _g1h;

  HeapRegion* _head;

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  HeapRegion* _survivor_head;
  HeapRegion* _survivor_tail;
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  HeapRegion* _curr;

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  uint        _length;
  uint        _survivor_length;
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  size_t      _last_sampled_rs_lengths;
  size_t      _sampled_rs_lengths;

  void         empty_list(HeapRegion* list);
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public:
  YoungList(G1CollectedHeap* g1h);

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  void         push_region(HeapRegion* hr);
  void         add_survivor_region(HeapRegion* hr);

  void         empty_list();
  bool         is_empty() { return _length == 0; }
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  uint         length() { return _length; }
  uint         survivor_length() { return _survivor_length; }
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  // Currently we do not keep track of the used byte sum for the
  // young list and the survivors and it'd be quite a lot of work to
  // do so. When we'll eventually replace the young list with
  // instances of HeapRegionLinkedList we'll get that for free. So,
  // we'll report the more accurate information then.
  size_t       eden_used_bytes() {
    assert(length() >= survivor_length(), "invariant");
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    return (size_t) (length() - survivor_length()) * HeapRegion::GrainBytes;
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  }
  size_t       survivor_used_bytes() {
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    return (size_t) survivor_length() * HeapRegion::GrainBytes;
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  }

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  void rs_length_sampling_init();
  bool rs_length_sampling_more();
  void rs_length_sampling_next();

  void reset_sampled_info() {
    _last_sampled_rs_lengths =   0;
  }
  size_t sampled_rs_lengths() { return _last_sampled_rs_lengths; }

  // for development purposes
  void reset_auxilary_lists();
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  void clear() { _head = NULL; _length = 0; }

  void clear_survivors() {
    _survivor_head    = NULL;
    _survivor_tail    = NULL;
    _survivor_length  = 0;
  }

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  HeapRegion* first_region() { return _head; }
  HeapRegion* first_survivor_region() { return _survivor_head; }
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  HeapRegion* last_survivor_region() { return _survivor_tail; }
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  // debugging
  bool          check_list_well_formed();
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  bool          check_list_empty(bool check_sample = true);
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  void          print();
};

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class MutatorAllocRegion : public G1AllocRegion {
protected:
  virtual HeapRegion* allocate_new_region(size_t word_size, bool force);
  virtual void retire_region(HeapRegion* alloc_region, size_t allocated_bytes);
public:
  MutatorAllocRegion()
    : G1AllocRegion("Mutator Alloc Region", false /* bot_updates */) { }
};

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class SurvivorGCAllocRegion : public G1AllocRegion {
protected:
  virtual HeapRegion* allocate_new_region(size_t word_size, bool force);
  virtual void retire_region(HeapRegion* alloc_region, size_t allocated_bytes);
public:
  SurvivorGCAllocRegion()
  : G1AllocRegion("Survivor GC Alloc Region", false /* bot_updates */) { }
};

class OldGCAllocRegion : public G1AllocRegion {
protected:
  virtual HeapRegion* allocate_new_region(size_t word_size, bool force);
  virtual void retire_region(HeapRegion* alloc_region, size_t allocated_bytes);
public:
  OldGCAllocRegion()
  : G1AllocRegion("Old GC Alloc Region", true /* bot_updates */) { }
};

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// The G1 STW is alive closure.
// An instance is embedded into the G1CH and used as the
// (optional) _is_alive_non_header closure in the STW
// reference processor. It is also extensively used during
// reference processing during STW evacuation pauses.
class G1STWIsAliveClosure: public BoolObjectClosure {
  G1CollectedHeap* _g1;
public:
  G1STWIsAliveClosure(G1CollectedHeap* g1) : _g1(g1) {}
  bool do_object_b(oop p);
};

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class RefineCardTableEntryClosure;
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class G1CollectedHeap : public SharedHeap {
  friend class VM_G1CollectForAllocation;
  friend class VM_G1CollectFull;
  friend class VM_G1IncCollectionPause;
  friend class VMStructs;
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  friend class MutatorAllocRegion;
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  friend class SurvivorGCAllocRegion;
  friend class OldGCAllocRegion;
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  // Closures used in implementation.
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  template <G1Barrier barrier, bool do_mark_object>
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  friend class G1ParCopyClosure;
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  friend class G1IsAliveClosure;
  friend class G1EvacuateFollowersClosure;
  friend class G1ParScanThreadState;
  friend class G1ParScanClosureSuper;
  friend class G1ParEvacuateFollowersClosure;
  friend class G1ParTask;
  friend class G1FreeGarbageRegionClosure;
  friend class RefineCardTableEntryClosure;
  friend class G1PrepareCompactClosure;
  friend class RegionSorter;
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  friend class RegionResetter;
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  friend class CountRCClosure;
  friend class EvacPopObjClosure;
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  friend class G1ParCleanupCTTask;
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  // Other related classes.
  friend class G1MarkSweep;

private:
  // The one and only G1CollectedHeap, so static functions can find it.
  static G1CollectedHeap* _g1h;

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  static size_t _humongous_object_threshold_in_words;

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  // Storage for the G1 heap.
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  VirtualSpace _g1_storage;
  MemRegion    _g1_reserved;

  // The part of _g1_storage that is currently committed.
  MemRegion _g1_committed;

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  // The master free list. It will satisfy all new region allocations.
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  FreeRegionList _free_list;
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  // The secondary free list which contains regions that have been
  // freed up during the cleanup process. This will be appended to the
  // master free list when appropriate.
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  FreeRegionList _secondary_free_list;
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  // It keeps track of the old regions.
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  HeapRegionSet _old_set;
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  // It keeps track of the humongous regions.
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  HeapRegionSet _humongous_set;
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  // The number of regions we could create by expansion.
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  uint _expansion_regions;
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  // The block offset table for the G1 heap.
  G1BlockOffsetSharedArray* _bot_shared;

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  // Tears down the region sets / lists so that they are empty and the
  // regions on the heap do not belong to a region set / list. The
  // only exception is the humongous set which we leave unaltered. If
  // free_list_only is true, it will only tear down the master free
  // list. It is called before a Full GC (free_list_only == false) or
  // before heap shrinking (free_list_only == true).
  void tear_down_region_sets(bool free_list_only);

  // Rebuilds the region sets / lists so that they are repopulated to
  // reflect the contents of the heap. The only exception is the
  // humongous set which was not torn down in the first place. If
  // free_list_only is true, it will only rebuild the master free
  // list. It is called after a Full GC (free_list_only == false) or
  // after heap shrinking (free_list_only == true).
  void rebuild_region_sets(bool free_list_only);
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  // The sequence of all heap regions in the heap.
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  HeapRegionSeq _hrs;
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  // Alloc region used to satisfy mutator allocation requests.
  MutatorAllocRegion _mutator_alloc_region;

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  // Alloc region used to satisfy allocation requests by the GC for
  // survivor objects.
  SurvivorGCAllocRegion _survivor_gc_alloc_region;

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  // PLAB sizing policy for survivors.
  PLABStats _survivor_plab_stats;

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  // Alloc region used to satisfy allocation requests by the GC for
  // old objects.
  OldGCAllocRegion _old_gc_alloc_region;

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  // PLAB sizing policy for tenured objects.
  PLABStats _old_plab_stats;

  PLABStats* stats_for_purpose(GCAllocPurpose purpose) {
    PLABStats* stats = NULL;

    switch (purpose) {
    case GCAllocForSurvived:
      stats = &_survivor_plab_stats;
      break;
    case GCAllocForTenured:
      stats = &_old_plab_stats;
      break;
    default:
      assert(false, "unrecognized GCAllocPurpose");
    }

    return stats;
  }

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  // The last old region we allocated to during the last GC.
  // Typically, it is not full so we should re-use it during the next GC.
  HeapRegion* _retained_old_gc_alloc_region;

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  // It specifies whether we should attempt to expand the heap after a
  // region allocation failure. If heap expansion fails we set this to
  // false so that we don't re-attempt the heap expansion (it's likely
  // that subsequent expansion attempts will also fail if one fails).
  // Currently, it is only consulted during GC and it's reset at the
  // start of each GC.
  bool _expand_heap_after_alloc_failure;

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  // It resets the mutator alloc region before new allocations can take place.
  void init_mutator_alloc_region();

  // It releases the mutator alloc region.
  void release_mutator_alloc_region();
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  // It initializes the GC alloc regions at the start of a GC.
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  void init_gc_alloc_regions(EvacuationInfo& evacuation_info);
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  // It releases the GC alloc regions at the end of a GC.
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  void release_gc_alloc_regions(uint no_of_gc_workers, EvacuationInfo& evacuation_info);
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  // It does any cleanup that needs to be done on the GC alloc regions
  // before a Full GC.
  void abandon_gc_alloc_regions();
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  // Helper for monitoring and management support.
  G1MonitoringSupport* _g1mm;

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  // Determines PLAB size for a particular allocation purpose.
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  size_t desired_plab_sz(GCAllocPurpose purpose);
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  // Outside of GC pauses, the number of bytes used in all regions other
  // than the current allocation region.
  size_t _summary_bytes_used;

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  // This is used for a quick test on whether a reference points into
  // the collection set or not. Basically, we have an array, with one
  // byte per region, and that byte denotes whether the corresponding
  // region is in the collection set or not. The entry corresponding
  // the bottom of the heap, i.e., region 0, is pointed to by
  // _in_cset_fast_test_base.  The _in_cset_fast_test field has been
  // biased so that it actually points to address 0 of the address
  // space, to make the test as fast as possible (we can simply shift
  // the address to address into it, instead of having to subtract the
  // bottom of the heap from the address before shifting it; basically
  // it works in the same way the card table works).
  bool* _in_cset_fast_test;

  // The allocated array used for the fast test on whether a reference
  // points into the collection set or not. This field is also used to
  // free the array.
  bool* _in_cset_fast_test_base;

  // The length of the _in_cset_fast_test_base array.
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  uint _in_cset_fast_test_length;
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  volatile unsigned _gc_time_stamp;
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  size_t* _surviving_young_words;

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  G1HRPrinter _hr_printer;

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  void setup_surviving_young_words();
  void update_surviving_young_words(size_t* surv_young_words);
  void cleanup_surviving_young_words();

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  // It decides whether an explicit GC should start a concurrent cycle
  // instead of doing a STW GC. Currently, a concurrent cycle is
  // explicitly started if:
  // (a) cause == _gc_locker and +GCLockerInvokesConcurrent, or
  // (b) cause == _java_lang_system_gc and +ExplicitGCInvokesConcurrent.
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  // (c) cause == _g1_humongous_allocation
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  bool should_do_concurrent_full_gc(GCCause::Cause cause);

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  // Keeps track of how many "old marking cycles" (i.e., Full GCs or
  // concurrent cycles) we have started.
  volatile unsigned int _old_marking_cycles_started;

  // Keeps track of how many "old marking cycles" (i.e., Full GCs or
  // concurrent cycles) we have completed.
  volatile unsigned int _old_marking_cycles_completed;
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  bool _concurrent_cycle_started;

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  // This is a non-product method that is helpful for testing. It is
  // called at the end of a GC and artificially expands the heap by
  // allocating a number of dead regions. This way we can induce very
  // frequent marking cycles and stress the cleanup / concurrent
  // cleanup code more (as all the regions that will be allocated by
  // this method will be found dead by the marking cycle).
  void allocate_dummy_regions() PRODUCT_RETURN;

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  // Clear RSets after a compaction. It also resets the GC time stamps.
  void clear_rsets_post_compaction();

  // If the HR printer is active, dump the state of the regions in the
  // heap after a compaction.
  void print_hrs_post_compaction();

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  double verify(bool guard, const char* msg);
  void verify_before_gc();
  void verify_after_gc();

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  void log_gc_header();
  void log_gc_footer(double pause_time_sec);

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  // These are macros so that, if the assert fires, we get the correct
  // line number, file, etc.

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#define heap_locking_asserts_err_msg(_extra_message_)                         \
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  err_msg("%s : Heap_lock locked: %s, at safepoint: %s, is VM thread: %s",    \
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          (_extra_message_),                                                  \
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          BOOL_TO_STR(Heap_lock->owned_by_self()),                            \
          BOOL_TO_STR(SafepointSynchronize::is_at_safepoint()),               \
          BOOL_TO_STR(Thread::current()->is_VM_thread()))
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#define assert_heap_locked()                                                  \
  do {                                                                        \
    assert(Heap_lock->owned_by_self(),                                        \
           heap_locking_asserts_err_msg("should be holding the Heap_lock"));  \
  } while (0)

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#define assert_heap_locked_or_at_safepoint(_should_be_vm_thread_)             \
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  do {                                                                        \
    assert(Heap_lock->owned_by_self() ||                                      \
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           (SafepointSynchronize::is_at_safepoint() &&                        \
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             ((_should_be_vm_thread_) == Thread::current()->is_VM_thread())), \
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           heap_locking_asserts_err_msg("should be holding the Heap_lock or " \
                                        "should be at a safepoint"));         \
  } while (0)

#define assert_heap_locked_and_not_at_safepoint()                             \
  do {                                                                        \
    assert(Heap_lock->owned_by_self() &&                                      \
                                    !SafepointSynchronize::is_at_safepoint(), \
          heap_locking_asserts_err_msg("should be holding the Heap_lock and " \
                                       "should not be at a safepoint"));      \
  } while (0)

#define assert_heap_not_locked()                                              \
  do {                                                                        \
    assert(!Heap_lock->owned_by_self(),                                       \
        heap_locking_asserts_err_msg("should not be holding the Heap_lock")); \
  } while (0)

#define assert_heap_not_locked_and_not_at_safepoint()                         \
  do {                                                                        \
    assert(!Heap_lock->owned_by_self() &&                                     \
                                    !SafepointSynchronize::is_at_safepoint(), \
      heap_locking_asserts_err_msg("should not be holding the Heap_lock and " \
                                   "should not be at a safepoint"));          \
  } while (0)

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#define assert_at_safepoint(_should_be_vm_thread_)                            \
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  do {                                                                        \
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    assert(SafepointSynchronize::is_at_safepoint() &&                         \
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              ((_should_be_vm_thread_) == Thread::current()->is_VM_thread()), \
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           heap_locking_asserts_err_msg("should be at a safepoint"));         \
  } while (0)

#define assert_not_at_safepoint()                                             \
  do {                                                                        \
    assert(!SafepointSynchronize::is_at_safepoint(),                          \
           heap_locking_asserts_err_msg("should not be at a safepoint"));     \
  } while (0)

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protected:

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  // The young region list.
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  YoungList*  _young_list;

  // The current policy object for the collector.
  G1CollectorPolicy* _g1_policy;

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  // This is the second level of trying to allocate a new region. If
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  // new_region() didn't find a region on the free_list, this call will
  // check whether there's anything available on the
  // secondary_free_list and/or wait for more regions to appear on
  // that list, if _free_regions_coming is set.
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  HeapRegion* new_region_try_secondary_free_list(bool is_old);
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  // Try to allocate a single non-humongous HeapRegion sufficient for
  // an allocation of the given word_size. If do_expand is true,
  // attempt to expand the heap if necessary to satisfy the allocation
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  // request. If the region is to be used as an old region or for a
  // humongous object, set is_old to true. If not, to false.
  HeapRegion* new_region(size_t word_size, bool is_old, bool do_expand);
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  // Attempt to satisfy a humongous allocation request of the given
  // size by finding a contiguous set of free regions of num_regions
  // length and remove them from the master free list. Return the
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  // index of the first region or G1_NULL_HRS_INDEX if the search
  // was unsuccessful.
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  uint humongous_obj_allocate_find_first(uint num_regions,
                                         size_t word_size);
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  // Initialize a contiguous set of free regions of length num_regions
  // and starting at index first so that they appear as a single
  // humongous region.
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  HeapWord* humongous_obj_allocate_initialize_regions(uint first,
                                                      uint num_regions,
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                                                      size_t word_size);

  // Attempt to allocate a humongous object of the given size. Return
  // NULL if unsuccessful.
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  HeapWord* humongous_obj_allocate(size_t word_size);
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  // The following two methods, allocate_new_tlab() and
  // mem_allocate(), are the two main entry points from the runtime
  // into the G1's allocation routines. They have the following
  // assumptions:
  //
  // * They should both be called outside safepoints.
  //
  // * They should both be called without holding the Heap_lock.
  //
  // * All allocation requests for new TLABs should go to
  //   allocate_new_tlab().
  //
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  // * All non-TLAB allocation requests should go to mem_allocate().
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  //
  // * If either call cannot satisfy the allocation request using the
  //   current allocating region, they will try to get a new one. If
  //   this fails, they will attempt to do an evacuation pause and
  //   retry the allocation.
  //
  // * If all allocation attempts fail, even after trying to schedule
  //   an evacuation pause, allocate_new_tlab() will return NULL,
  //   whereas mem_allocate() will attempt a heap expansion and/or
  //   schedule a Full GC.
  //
  // * We do not allow humongous-sized TLABs. So, allocate_new_tlab
  //   should never be called with word_size being humongous. All
  //   humongous allocation requests should go to mem_allocate() which
  //   will satisfy them with a special path.

  virtual HeapWord* allocate_new_tlab(size_t word_size);

  virtual HeapWord* mem_allocate(size_t word_size,
                                 bool*  gc_overhead_limit_was_exceeded);

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  // The following three methods take a gc_count_before_ret
  // parameter which is used to return the GC count if the method
  // returns NULL. Given that we are required to read the GC count
  // while holding the Heap_lock, and these paths will take the
  // Heap_lock at some point, it's easier to get them to read the GC
  // count while holding the Heap_lock before they return NULL instead
  // of the caller (namely: mem_allocate()) having to also take the
  // Heap_lock just to read the GC count.

  // First-level mutator allocation attempt: try to allocate out of
  // the mutator alloc region without taking the Heap_lock. This
  // should only be used for non-humongous allocations.
  inline HeapWord* attempt_allocation(size_t word_size,
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                                      unsigned int* gc_count_before_ret,
                                      int* gclocker_retry_count_ret);
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  // Second-level mutator allocation attempt: take the Heap_lock and
  // retry the allocation attempt, potentially scheduling a GC
  // pause. This should only be used for non-humongous allocations.
  HeapWord* attempt_allocation_slow(size_t word_size,
582 583
                                    unsigned int* gc_count_before_ret,
                                    int* gclocker_retry_count_ret);
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  // Takes the Heap_lock and attempts a humongous allocation. It can
  // potentially schedule a GC pause.
587
  HeapWord* attempt_allocation_humongous(size_t word_size,
588 589
                                         unsigned int* gc_count_before_ret,
                                         int* gclocker_retry_count_ret);
590

591 592 593 594
  // Allocation attempt that should be called during safepoints (e.g.,
  // at the end of a successful GC). expect_null_mutator_alloc_region
  // specifies whether the mutator alloc region is expected to be NULL
  // or not.
595
  HeapWord* attempt_allocation_at_safepoint(size_t word_size,
596
                                       bool expect_null_mutator_alloc_region);
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  // It dirties the cards that cover the block so that so that the post
  // write barrier never queues anything when updating objects on this
  // block. It is assumed (and in fact we assert) that the block
  // belongs to a young region.
  inline void dirty_young_block(HeapWord* start, size_t word_size);
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  // Allocate blocks during garbage collection. Will ensure an
  // allocation region, either by picking one or expanding the
  // heap, and then allocate a block of the given size. The block
  // may not be a humongous - it must fit into a single heap region.
  HeapWord* par_allocate_during_gc(GCAllocPurpose purpose, size_t word_size);

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  HeapWord* allocate_during_gc_slow(GCAllocPurpose purpose,
                                    HeapRegion*    alloc_region,
                                    bool           par,
                                    size_t         word_size);

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  // Ensure that no further allocations can happen in "r", bearing in mind
  // that parallel threads might be attempting allocations.
  void par_allocate_remaining_space(HeapRegion* r);

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  // Allocation attempt during GC for a survivor object / PLAB.
  inline HeapWord* survivor_attempt_allocation(size_t word_size);
621

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  // Allocation attempt during GC for an old object / PLAB.
  inline HeapWord* old_attempt_allocation(size_t word_size);
624

625 626 627
  // These methods are the "callbacks" from the G1AllocRegion class.

  // For mutator alloc regions.
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  HeapRegion* new_mutator_alloc_region(size_t word_size, bool force);
  void retire_mutator_alloc_region(HeapRegion* alloc_region,
                                   size_t allocated_bytes);

632
  // For GC alloc regions.
633
  HeapRegion* new_gc_alloc_region(size_t word_size, uint count,
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                                  GCAllocPurpose ap);
  void retire_gc_alloc_region(HeapRegion* alloc_region,
                              size_t allocated_bytes, GCAllocPurpose ap);

638
  // - if explicit_gc is true, the GC is for a System.gc() or a heap
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  //   inspection request and should collect the entire heap
  // - if clear_all_soft_refs is true, all soft references should be
  //   cleared during the GC
642
  // - if explicit_gc is false, word_size describes the allocation that
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  //   the GC should attempt (at least) to satisfy
  // - it returns false if it is unable to do the collection due to the
  //   GC locker being active, true otherwise
  bool do_collection(bool explicit_gc,
647
                     bool clear_all_soft_refs,
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                     size_t word_size);

  // Callback from VM_G1CollectFull operation.
  // Perform a full collection.
652
  virtual void do_full_collection(bool clear_all_soft_refs);
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  // Resize the heap if necessary after a full collection.  If this is
  // after a collect-for allocation, "word_size" is the allocation size,
  // and will be considered part of the used portion of the heap.
  void resize_if_necessary_after_full_collection(size_t word_size);

  // Callback from VM_G1CollectForAllocation operation.
  // This function does everything necessary/possible to satisfy a
  // failed allocation request (including collection, expansion, etc.)
662
  HeapWord* satisfy_failed_allocation(size_t word_size, bool* succeeded);
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  // Attempting to expand the heap sufficiently
  // to support an allocation of the given "word_size".  If
  // successful, perform the allocation and return the address of the
  // allocated block, or else "NULL".
668
  HeapWord* expand_and_allocate(size_t word_size);
669

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  // Process any reference objects discovered during
  // an incremental evacuation pause.
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  void process_discovered_references(uint no_of_gc_workers);
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  // Enqueue any remaining discovered references
  // after processing.
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  void enqueue_discovered_references(uint no_of_gc_workers);
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678
public:
679

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  G1MonitoringSupport* g1mm() {
    assert(_g1mm != NULL, "should have been initialized");
    return _g1mm;
  }
684

685
  // Expand the garbage-first heap by at least the given size (in bytes!).
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  // Returns true if the heap was expanded by the requested amount;
  // false otherwise.
688
  // (Rounds up to a HeapRegion boundary.)
689
  bool expand(size_t expand_bytes);
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  // Do anything common to GC's.
  virtual void gc_prologue(bool full);
  virtual void gc_epilogue(bool full);

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  // We register a region with the fast "in collection set" test. We
  // simply set to true the array slot corresponding to this region.
  void register_region_with_in_cset_fast_test(HeapRegion* r) {
    assert(_in_cset_fast_test_base != NULL, "sanity");
    assert(r->in_collection_set(), "invariant");
700
    uint index = r->hrs_index();
701
    assert(index < _in_cset_fast_test_length, "invariant");
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    assert(!_in_cset_fast_test_base[index], "invariant");
    _in_cset_fast_test_base[index] = true;
  }

  // This is a fast test on whether a reference points into the
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  // collection set or not. Assume that the reference
  // points into the heap.
709
  inline bool in_cset_fast_test(oop obj);
710

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  void clear_cset_fast_test() {
    assert(_in_cset_fast_test_base != NULL, "sanity");
    memset(_in_cset_fast_test_base, false,
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           (size_t) _in_cset_fast_test_length * sizeof(bool));
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  }

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  // This is called at the start of either a concurrent cycle or a Full
  // GC to update the number of old marking cycles started.
  void increment_old_marking_cycles_started();

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  // This is called at the end of either a concurrent cycle or a Full
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  // GC to update the number of old marking cycles completed. Those two
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  // can happen in a nested fashion, i.e., we start a concurrent
  // cycle, a Full GC happens half-way through it which ends first,
  // and then the cycle notices that a Full GC happened and ends
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  // too. The concurrent parameter is a boolean to help us do a bit
  // tighter consistency checking in the method. If concurrent is
  // false, the caller is the inner caller in the nesting (i.e., the
  // Full GC). If concurrent is true, the caller is the outer caller
  // in this nesting (i.e., the concurrent cycle). Further nesting is
731
  // not currently supported. The end of this call also notifies
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  // the FullGCCount_lock in case a Java thread is waiting for a full
  // GC to happen (e.g., it called System.gc() with
734
  // +ExplicitGCInvokesConcurrent).
735
  void increment_old_marking_cycles_completed(bool concurrent);
736

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  unsigned int old_marking_cycles_completed() {
    return _old_marking_cycles_completed;
739 740
  }

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  void register_concurrent_cycle_start(const Ticks& start_time);
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  void register_concurrent_cycle_end();
  void trace_heap_after_concurrent_cycle();

  G1YCType yc_type();

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  G1HRPrinter* hr_printer() { return &_hr_printer; }

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  // Frees a non-humongous region by initializing its contents and
  // adding it to the free list that's passed as a parameter (this is
  // usually a local list which will be appended to the master free
  // list later). The used bytes of freed regions are accumulated in
  // pre_used. If par is true, the region's RSet will not be freed
  // up. The assumption is that this will be done later.
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  // The locked parameter indicates if the caller has already taken
  // care of proper synchronization. This may allow some optimizations.
757 758
  void free_region(HeapRegion* hr,
                   FreeRegionList* free_list,
759 760
                   bool par,
                   bool locked = false);
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  // Frees a humongous region by collapsing it into individual regions
  // and calling free_region() for each of them. The freed regions
  // will be added to the free list that's passed as a parameter (this
  // is usually a local list which will be appended to the master free
  // list later). The used bytes of freed regions are accumulated in
  // pre_used. If par is true, the region's RSet will not be freed
  // up. The assumption is that this will be done later.
  void free_humongous_region(HeapRegion* hr,
                             FreeRegionList* free_list,
                             bool par);
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protected:

  // Shrink the garbage-first heap by at most the given size (in bytes!).
  // (Rounds down to a HeapRegion boundary.)
  virtual void shrink(size_t expand_bytes);
  void shrink_helper(size_t expand_bytes);

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  #if TASKQUEUE_STATS
  static void print_taskqueue_stats_hdr(outputStream* const st = gclog_or_tty);
  void print_taskqueue_stats(outputStream* const st = gclog_or_tty) const;
  void reset_taskqueue_stats();
  #endif // TASKQUEUE_STATS

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  // Schedule the VM operation that will do an evacuation pause to
  // satisfy an allocation request of word_size. *succeeded will
  // return whether the VM operation was successful (it did do an
  // evacuation pause) or not (another thread beat us to it or the GC
  // locker was active). Given that we should not be holding the
  // Heap_lock when we enter this method, we will pass the
  // gc_count_before (i.e., total_collections()) as a parameter since
  // it has to be read while holding the Heap_lock. Currently, both
  // methods that call do_collection_pause() release the Heap_lock
  // before the call, so it's easy to read gc_count_before just before.
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  HeapWord* do_collection_pause(size_t         word_size,
                                unsigned int   gc_count_before,
                                bool*          succeeded,
                                GCCause::Cause gc_cause);
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  // The guts of the incremental collection pause, executed by the vm
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  // thread. It returns false if it is unable to do the collection due
  // to the GC locker being active, true otherwise
  bool do_collection_pause_at_safepoint(double target_pause_time_ms);
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  // Actually do the work of evacuating the collection set.
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  void evacuate_collection_set(EvacuationInfo& evacuation_info);
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  // The g1 remembered set of the heap.
  G1RemSet* _g1_rem_set;

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  // A set of cards that cover the objects for which the Rsets should be updated
  // concurrently after the collection.
  DirtyCardQueueSet _dirty_card_queue_set;

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  // The closure used to refine a single card.
  RefineCardTableEntryClosure* _refine_cte_cl;

  // A function to check the consistency of dirty card logs.
  void check_ct_logs_at_safepoint();

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  // A DirtyCardQueueSet that is used to hold cards that contain
  // references into the current collection set. This is used to
  // update the remembered sets of the regions in the collection
  // set in the event of an evacuation failure.
  DirtyCardQueueSet _into_cset_dirty_card_queue_set;

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  // After a collection pause, make the regions in the CS into free
  // regions.
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  void free_collection_set(HeapRegion* cs_head, EvacuationInfo& evacuation_info);
830

831 832 833 834
  // Abandon the current collection set without recording policy
  // statistics or updating free lists.
  void abandon_collection_set(HeapRegion* cs_head);

835 836
  // Applies "scan_non_heap_roots" to roots outside the heap,
  // "scan_rs" to roots inside the heap (having done "set_region" to
837 838
  // indicate the region in which the root resides),
  // and does "scan_metadata" If "scan_rs" is
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  // NULL, then this step is skipped.  The "worker_i"
  // param is for use with parallel roots processing, and should be
  // the "i" of the calling parallel worker thread's work(i) function.
  // In the sequential case this param will be ignored.
843
  void g1_process_strong_roots(bool is_scavenging,
844
                               ScanningOption so,
845 846
                               OopClosure* scan_non_heap_roots,
                               OopsInHeapRegionClosure* scan_rs,
847
                               G1KlassScanClosure* scan_klasses,
848
                               uint worker_i);
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  // Apply "blk" to all the weak roots of the system.  These include
  // JNI weak roots, the code cache, system dictionary, symbol table,
  // string table, and referents of reachable weak refs.
853
  void g1_process_weak_roots(OopClosure* root_closure);
854

855 856 857 858 859
  // Notifies all the necessary spaces that the committed space has
  // been updated (either expanded or shrunk). It should be called
  // after _g1_storage is updated.
  void update_committed_space(HeapWord* old_end, HeapWord* new_end);

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  // The concurrent marker (and the thread it runs in.)
  ConcurrentMark* _cm;
  ConcurrentMarkThread* _cmThread;
  bool _mark_in_progress;

  // The concurrent refiner.
  ConcurrentG1Refine* _cg1r;

  // The parallel task queues
  RefToScanQueueSet *_task_queues;

  // True iff a evacuation has failed in the current collection.
  bool _evacuation_failed;

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  EvacuationFailedInfo* _evacuation_failed_info_array;
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  // Failed evacuations cause some logical from-space objects to have
  // forwarding pointers to themselves.  Reset them.
  void remove_self_forwarding_pointers();

880 881 882
  // Together, these store an object with a preserved mark, and its mark value.
  Stack<oop, mtGC>     _objs_with_preserved_marks;
  Stack<markOop, mtGC> _preserved_marks_of_objs;
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  // Preserve the mark of "obj", if necessary, in preparation for its mark
  // word being overwritten with a self-forwarding-pointer.
  void preserve_mark_if_necessary(oop obj, markOop m);

  // The stack of evac-failure objects left to be scanned.
  GrowableArray<oop>*    _evac_failure_scan_stack;
  // The closure to apply to evac-failure objects.

  OopsInHeapRegionClosure* _evac_failure_closure;
  // Set the field above.
  void
  set_evac_failure_closure(OopsInHeapRegionClosure* evac_failure_closure) {
    _evac_failure_closure = evac_failure_closure;
  }

  // Push "obj" on the scan stack.
  void push_on_evac_failure_scan_stack(oop obj);
  // Process scan stack entries until the stack is empty.
  void drain_evac_failure_scan_stack();
  // True iff an invocation of "drain_scan_stack" is in progress; to
  // prevent unnecessary recursion.
  bool _drain_in_progress;

  // Do any necessary initialization for evacuation-failure handling.
  // "cl" is the closure that will be used to process evac-failure
  // objects.
  void init_for_evac_failure(OopsInHeapRegionClosure* cl);
  // Do any necessary cleanup for evacuation-failure handling data
  // structures.
  void finalize_for_evac_failure();

  // An attempt to evacuate "obj" has failed; take necessary steps.
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  oop handle_evacuation_failure_par(G1ParScanThreadState* _par_scan_state, oop obj);
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  void handle_evacuation_failure_common(oop obj, markOop m);

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#ifndef PRODUCT
  // Support for forcing evacuation failures. Analogous to
  // PromotionFailureALot for the other collectors.

  // Records whether G1EvacuationFailureALot should be in effect
  // for the current GC
  bool _evacuation_failure_alot_for_current_gc;

  // Used to record the GC number for interval checking when
  // determining whether G1EvaucationFailureALot is in effect
  // for the current GC.
  size_t _evacuation_failure_alot_gc_number;

  // Count of the number of evacuations between failures.
  volatile size_t _evacuation_failure_alot_count;

  // Set whether G1EvacuationFailureALot should be in effect
  // for the current GC (based upon the type of GC and which
  // command line flags are set);
  inline bool evacuation_failure_alot_for_gc_type(bool gcs_are_young,
                                                  bool during_initial_mark,
                                                  bool during_marking);

  inline void set_evacuation_failure_alot_for_current_gc();

  // Return true if it's time to cause an evacuation failure.
  inline bool evacuation_should_fail();

  // Reset the G1EvacuationFailureALot counters.  Should be called at
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  // the end of an evacuation pause in which an evacuation failure occurred.
949 950 951
  inline void reset_evacuation_should_fail();
#endif // !PRODUCT

952 953
  // ("Weak") Reference processing support.
  //
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  // G1 has 2 instances of the reference processor class. One
955 956 957 958 959 960 961 962 963 964 965 966 967 968 969 970 971 972 973 974 975 976 977 978 979 980 981 982 983 984 985 986 987 988 989 990 991 992 993 994 995 996 997 998 999 1000 1001 1002 1003
  // (_ref_processor_cm) handles reference object discovery
  // and subsequent processing during concurrent marking cycles.
  //
  // The other (_ref_processor_stw) handles reference object
  // discovery and processing during full GCs and incremental
  // evacuation pauses.
  //
  // During an incremental pause, reference discovery will be
  // temporarily disabled for _ref_processor_cm and will be
  // enabled for _ref_processor_stw. At the end of the evacuation
  // pause references discovered by _ref_processor_stw will be
  // processed and discovery will be disabled. The previous
  // setting for reference object discovery for _ref_processor_cm
  // will be re-instated.
  //
  // At the start of marking:
  //  * Discovery by the CM ref processor is verified to be inactive
  //    and it's discovered lists are empty.
  //  * Discovery by the CM ref processor is then enabled.
  //
  // At the end of marking:
  //  * Any references on the CM ref processor's discovered
  //    lists are processed (possibly MT).
  //
  // At the start of full GC we:
  //  * Disable discovery by the CM ref processor and
  //    empty CM ref processor's discovered lists
  //    (without processing any entries).
  //  * Verify that the STW ref processor is inactive and it's
  //    discovered lists are empty.
  //  * Temporarily set STW ref processor discovery as single threaded.
  //  * Temporarily clear the STW ref processor's _is_alive_non_header
  //    field.
  //  * Finally enable discovery by the STW ref processor.
  //
  // The STW ref processor is used to record any discovered
  // references during the full GC.
  //
  // At the end of a full GC we:
  //  * Enqueue any reference objects discovered by the STW ref processor
  //    that have non-live referents. This has the side-effect of
  //    making the STW ref processor inactive by disabling discovery.
  //  * Verify that the CM ref processor is still inactive
  //    and no references have been placed on it's discovered
  //    lists (also checked as a precondition during initial marking).

  // The (stw) reference processor...
  ReferenceProcessor* _ref_processor_stw;

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  STWGCTimer* _gc_timer_stw;
  ConcurrentGCTimer* _gc_timer_cm;

  G1OldTracer* _gc_tracer_cm;
  G1NewTracer* _gc_tracer_stw;

1010 1011 1012 1013 1014 1015 1016 1017 1018 1019 1020 1021 1022 1023 1024 1025 1026
  // During reference object discovery, the _is_alive_non_header
  // closure (if non-null) is applied to the referent object to
  // determine whether the referent is live. If so then the
  // reference object does not need to be 'discovered' and can
  // be treated as a regular oop. This has the benefit of reducing
  // the number of 'discovered' reference objects that need to
  // be processed.
  //
  // Instance of the is_alive closure for embedding into the
  // STW reference processor as the _is_alive_non_header field.
  // Supplying a value for the _is_alive_non_header field is
  // optional but doing so prevents unnecessary additions to
  // the discovered lists during reference discovery.
  G1STWIsAliveClosure _is_alive_closure_stw;

  // The (concurrent marking) reference processor...
  ReferenceProcessor* _ref_processor_cm;
1027

1028 1029 1030 1031 1032 1033 1034
  // Instance of the concurrent mark is_alive closure for embedding
  // into the Concurrent Marking reference processor as the
  // _is_alive_non_header field. Supplying a value for the
  // _is_alive_non_header field is optional but doing so prevents
  // unnecessary additions to the discovered lists during reference
  // discovery.
  G1CMIsAliveClosure _is_alive_closure_cm;
1035

1036 1037 1038 1039 1040 1041 1042 1043 1044 1045
  // Cache used by G1CollectedHeap::start_cset_region_for_worker().
  HeapRegion** _worker_cset_start_region;

  // Time stamp to validate the regions recorded in the cache
  // used by G1CollectedHeap::start_cset_region_for_worker().
  // The heap region entry for a given worker is valid iff
  // the associated time stamp value matches the current value
  // of G1CollectedHeap::_gc_time_stamp.
  unsigned int* _worker_cset_start_region_time_stamp;

1046
  enum G1H_process_strong_roots_tasks {
1047
    G1H_PS_filter_satb_buffers,
1048 1049 1050 1051 1052 1053 1054
    G1H_PS_refProcessor_oops_do,
    // Leave this one last.
    G1H_PS_NumElements
  };

  SubTasksDone* _process_strong_tasks;

1055
  volatile bool _free_regions_coming;
1056 1057

public:
1058 1059 1060

  SubTasksDone* process_strong_tasks() { return _process_strong_tasks; }

1061 1062
  void set_refine_cte_cl_concurrency(bool concurrent);

1063
  RefToScanQueue *task_queue(int i) const;
1064

1065 1066 1067
  // A set of cards where updates happened during the GC
  DirtyCardQueueSet& dirty_card_queue_set() { return _dirty_card_queue_set; }

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  // A DirtyCardQueueSet that is used to hold cards that contain
  // references into the current collection set. This is used to
  // update the remembered sets of the regions in the collection
  // set in the event of an evacuation failure.
  DirtyCardQueueSet& into_cset_dirty_card_queue_set()
        { return _into_cset_dirty_card_queue_set; }

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  // Create a G1CollectedHeap with the specified policy.
  // Must call the initialize method afterwards.
  // May not return if something goes wrong.
  G1CollectedHeap(G1CollectorPolicy* policy);

  // Initialize the G1CollectedHeap to have the initial and
1081
  // maximum sizes and remembered and barrier sets
1082 1083 1084
  // specified by the policy object.
  jint initialize();

1085 1086 1087
  // Return the (conservative) maximum heap alignment for any G1 heap
  static size_t conservative_max_heap_alignment();

1088
  // Initialize weak reference processing.
1089
  virtual void ref_processing_init();
1090

1091
  void set_par_threads(uint t) {
1092
    SharedHeap::set_par_threads(t);
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    // Done in SharedHeap but oddly there are
    // two _process_strong_tasks's in a G1CollectedHeap
    // so do it here too.
    _process_strong_tasks->set_n_threads(t);
  }

  // Set _n_par_threads according to a policy TBD.
  void set_par_threads();

  void set_n_termination(int t) {
1103
    _process_strong_tasks->set_n_threads(t);
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  }

  virtual CollectedHeap::Name kind() const {
    return CollectedHeap::G1CollectedHeap;
  }

  // The current policy object for the collector.
  G1CollectorPolicy* g1_policy() const { return _g1_policy; }

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  virtual CollectorPolicy* collector_policy() const { return (CollectorPolicy*) g1_policy(); }

1115 1116 1117 1118 1119 1120 1121 1122 1123 1124 1125 1126
  // Adaptive size policy.  No such thing for g1.
  virtual AdaptiveSizePolicy* size_policy() { return NULL; }

  // The rem set and barrier set.
  G1RemSet* g1_rem_set() const { return _g1_rem_set; }

  unsigned get_gc_time_stamp() {
    return _gc_time_stamp;
  }

  void reset_gc_time_stamp() {
    _gc_time_stamp = 0;
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    OrderAccess::fence();
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    // Clear the cached CSet starting regions and time stamps.
    // Their validity is dependent on the GC timestamp.
    clear_cset_start_regions();
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  }

1133 1134
  void check_gc_time_stamps() PRODUCT_RETURN;

1135 1136 1137
  void increment_gc_time_stamp() {
    ++_gc_time_stamp;
    OrderAccess::fence();
1138 1139
  }

1140 1141 1142 1143 1144
  // Reset the given region's GC timestamp. If it's starts humongous,
  // also reset the GC timestamp of its corresponding
  // continues humongous regions too.
  void reset_gc_time_stamps(HeapRegion* hr);

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  void iterate_dirty_card_closure(CardTableEntryClosure* cl,
                                  DirtyCardQueue* into_cset_dcq,
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                                  bool concurrent, uint worker_i);
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  // The shared block offset table array.
  G1BlockOffsetSharedArray* bot_shared() const { return _bot_shared; }

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  // Reference Processing accessors

  // The STW reference processor....
  ReferenceProcessor* ref_processor_stw() const { return _ref_processor_stw; }

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  // The Concurrent Marking reference processor...
1158
  ReferenceProcessor* ref_processor_cm() const { return _ref_processor_cm; }
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  ConcurrentGCTimer* gc_timer_cm() const { return _gc_timer_cm; }
  G1OldTracer* gc_tracer_cm() const { return _gc_tracer_cm; }

1163 1164
  virtual size_t capacity() const;
  virtual size_t used() const;
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  // This should be called when we're not holding the heap lock. The
  // result might be a bit inaccurate.
  size_t used_unlocked() const;
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  size_t recalculate_used() const;

  // These virtual functions do the actual allocation.
  // Some heaps may offer a contiguous region for shared non-blocking
  // allocation, via inlined code (by exporting the address of the top and
  // end fields defining the extent of the contiguous allocation region.)
  // But G1CollectedHeap doesn't yet support this.

  // Return an estimate of the maximum allocation that could be performed
  // without triggering any collection or expansion activity.  In a
  // generational collector, for example, this is probably the largest
  // allocation that could be supported (without expansion) in the youngest
  // generation.  It is "unsafe" because no locks are taken; the result
  // should be treated as an approximation, not a guarantee, for use in
  // heuristic resizing decisions.
  virtual size_t unsafe_max_alloc();

  virtual bool is_maximal_no_gc() const {
    return _g1_storage.uncommitted_size() == 0;
  }

  // The total number of regions in the heap.
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  uint n_regions() { return _hrs.length(); }
1191

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  // The max number of regions in the heap.
1193
  uint max_regions() { return _hrs.max_length(); }
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  // The number of regions that are completely free.
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  uint free_regions() { return _free_list.length(); }
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  // The number of regions that are not completely free.
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  uint used_regions() { return n_regions() - free_regions(); }
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  // The number of regions available for "regular" expansion.
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  uint expansion_regions() { return _expansion_regions; }
1203

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  // Factory method for HeapRegion instances. It will return NULL if
  // the allocation fails.
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  HeapRegion* new_heap_region(uint hrs_index, HeapWord* bottom);
1207

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  void verify_not_dirty_region(HeapRegion* hr) PRODUCT_RETURN;
  void verify_dirty_region(HeapRegion* hr) PRODUCT_RETURN;
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  void verify_dirty_young_list(HeapRegion* head) PRODUCT_RETURN;
  void verify_dirty_young_regions() PRODUCT_RETURN;

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  // verify_region_sets() performs verification over the region
  // lists. It will be compiled in the product code to be used when
  // necessary (i.e., during heap verification).
  void verify_region_sets();

  // verify_region_sets_optional() is planted in the code for
  // list verification in non-product builds (and it can be enabled in
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  // product builds by defining HEAP_REGION_SET_FORCE_VERIFY to be 1).
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#if HEAP_REGION_SET_FORCE_VERIFY
  void verify_region_sets_optional() {
    verify_region_sets();
  }
#else // HEAP_REGION_SET_FORCE_VERIFY
  void verify_region_sets_optional() { }
#endif // HEAP_REGION_SET_FORCE_VERIFY

#ifdef ASSERT
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  bool is_on_master_free_list(HeapRegion* hr) {
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    return hr->containing_set() == &_free_list;
  }
#endif // ASSERT

  // Wrapper for the region list operations that can be called from
  // methods outside this class.

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  void secondary_free_list_add(FreeRegionList* list) {
    _secondary_free_list.add_ordered(list);
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  }

  void append_secondary_free_list() {
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    _free_list.add_ordered(&_secondary_free_list);
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  }

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  void append_secondary_free_list_if_not_empty_with_lock() {
    // If the secondary free list looks empty there's no reason to
    // take the lock and then try to append it.
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    if (!_secondary_free_list.is_empty()) {
      MutexLockerEx x(SecondaryFreeList_lock, Mutex::_no_safepoint_check_flag);
      append_secondary_free_list();
    }
  }

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  inline void old_set_remove(HeapRegion* hr);
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  size_t non_young_capacity_bytes() {
    return _old_set.total_capacity_bytes() + _humongous_set.total_capacity_bytes();
  }

1261 1262 1263 1264
  void set_free_regions_coming();
  void reset_free_regions_coming();
  bool free_regions_coming() { return _free_regions_coming; }
  void wait_while_free_regions_coming();
1265

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  // Determine whether the given region is one that we are using as an
  // old GC alloc region.
  bool is_old_gc_alloc_region(HeapRegion* hr) {
    return hr == _retained_old_gc_alloc_region;
  }

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  // Perform a collection of the heap; intended for use in implementing
  // "System.gc".  This probably implies as full a collection as the
  // "CollectedHeap" supports.
  virtual void collect(GCCause::Cause cause);

  // The same as above but assume that the caller holds the Heap_lock.
  void collect_locked(GCCause::Cause cause);

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  // True iff an evacuation has failed in the most-recent collection.
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  bool evacuation_failed() { return _evacuation_failed; }

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  void remove_from_old_sets(const HeapRegionSetCount& old_regions_removed, const HeapRegionSetCount& humongous_regions_removed);
  void prepend_to_freelist(FreeRegionList* list);
  void decrement_summary_bytes(size_t bytes);
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  // Returns "TRUE" iff "p" points into the committed areas of the heap.
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  virtual bool is_in(const void* p) const;

  // Return "TRUE" iff the given object address is within the collection
  // set.
  inline bool obj_in_cs(oop obj);

  // Return "TRUE" iff the given object address is in the reserved
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  // region of g1.
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  bool is_in_g1_reserved(const void* p) const {
    return _g1_reserved.contains(p);
  }

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  // Returns a MemRegion that corresponds to the space that has been
  // reserved for the heap
  MemRegion g1_reserved() {
    return _g1_reserved;
  }

  // Returns a MemRegion that corresponds to the space that has been
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  // committed in the heap
  MemRegion g1_committed() {
    return _g1_committed;
  }

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  virtual bool is_in_closed_subset(const void* p) const;
1313

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  G1SATBCardTableModRefBS* g1_barrier_set() {
    return (G1SATBCardTableModRefBS*) barrier_set();
  }

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  // This resets the card table to all zeros.  It is used after
  // a collection pause which used the card table to claim cards.
  void cleanUpCardTable();

  // Iteration functions.

  // Iterate over all the ref-containing fields of all objects, calling
  // "cl.do_oop" on each.
1326
  virtual void oop_iterate(ExtendedOopClosure* cl);
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  // Same as above, restricted to a memory region.
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  void oop_iterate(MemRegion mr, ExtendedOopClosure* cl);
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  // Iterate over all objects, calling "cl.do_object" on each.
1332 1333
  virtual void object_iterate(ObjectClosure* cl);

1334
  virtual void safe_object_iterate(ObjectClosure* cl) {
1335
    object_iterate(cl);
1336
  }
1337 1338 1339 1340 1341 1342

  // Iterate over all spaces in use in the heap, in ascending address order.
  virtual void space_iterate(SpaceClosure* cl);

  // Iterate over heap regions, in address order, terminating the
  // iteration early if the "doHeapRegion" method returns "true".
1343
  void heap_region_iterate(HeapRegionClosure* blk) const;
1344

1345
  // Return the region with the given index. It assumes the index is valid.
1346
  inline HeapRegion* region_at(uint index) const;
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  // Divide the heap region sequence into "chunks" of some size (the number
  // of regions divided by the number of parallel threads times some
  // overpartition factor, currently 4).  Assumes that this will be called
  // in parallel by ParallelGCThreads worker threads with discinct worker
  // ids in the range [0..max(ParallelGCThreads-1, 1)], that all parallel
  // calls will use the same "claim_value", and that that claim value is
  // different from the claim_value of any heap region before the start of
  // the iteration.  Applies "blk->doHeapRegion" to each of the regions, by
  // attempting to claim the first region in each chunk, and, if
  // successful, applying the closure to each region in the chunk (and
  // setting the claim value of the second and subsequent regions of the
  // chunk.)  For now requires that "doHeapRegion" always returns "false",
  // i.e., that a closure never attempt to abort a traversal.
  void heap_region_par_iterate_chunked(HeapRegionClosure* blk,
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                                       uint worker,
                                       uint no_of_par_workers,
1364 1365
                                       jint claim_value);

1366 1367 1368
  // It resets all the region claim values to the default.
  void reset_heap_region_claim_values();

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  // Resets the claim values of regions in the current
  // collection set to the default.
  void reset_cset_heap_region_claim_values();

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#ifdef ASSERT
  bool check_heap_region_claim_values(jint claim_value);
1375 1376 1377 1378

  // Same as the routine above but only checks regions in the
  // current collection set.
  bool check_cset_heap_region_claim_values(jint claim_value);
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#endif // ASSERT

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  // Clear the cached cset start regions and (more importantly)
  // the time stamps. Called when we reset the GC time stamp.
  void clear_cset_start_regions();

  // Given the id of a worker, obtain or calculate a suitable
  // starting region for iterating over the current collection set.
1387
  HeapRegion* start_cset_region_for_worker(uint worker_i);
1388

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  // This is a convenience method that is used by the
  // HeapRegionIterator classes to calculate the starting region for
  // each worker so that they do not all start from the same region.
  HeapRegion* start_region_for_worker(uint worker_i, uint no_of_par_workers);

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  // Iterate over the regions (if any) in the current collection set.
  void collection_set_iterate(HeapRegionClosure* blk);

  // As above but starting from region r
  void collection_set_iterate_from(HeapRegion* r, HeapRegionClosure *blk);

  // Returns the first (lowest address) compactible space in the heap.
  virtual CompactibleSpace* first_compactible_space();

  // A CollectedHeap will contain some number of spaces.  This finds the
  // space containing a given address, or else returns NULL.
  virtual Space* space_containing(const void* addr) const;

  // A G1CollectedHeap will contain some number of heap regions.  This
  // finds the region containing a given address, or else returns NULL.
1409 1410
  template <class T>
  inline HeapRegion* heap_region_containing(const T addr) const;
1411 1412 1413 1414

  // Like the above, but requires "addr" to be in the heap (to avoid a
  // null-check), and unlike the above, may return an continuing humongous
  // region.
1415 1416
  template <class T>
  inline HeapRegion* heap_region_containing_raw(const T addr) const;
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  // A CollectedHeap is divided into a dense sequence of "blocks"; that is,
  // each address in the (reserved) heap is a member of exactly
  // one block.  The defining characteristic of a block is that it is
  // possible to find its size, and thus to progress forward to the next
  // block.  (Blocks may be of different sizes.)  Thus, blocks may
  // represent Java objects, or they might be free blocks in a
  // free-list-based heap (or subheap), as long as the two kinds are
  // distinguishable and the size of each is determinable.

  // Returns the address of the start of the "block" that contains the
  // address "addr".  We say "blocks" instead of "object" since some heaps
  // may not pack objects densely; a chunk may either be an object or a
  // non-object.
  virtual HeapWord* block_start(const void* addr) const;

  // Requires "addr" to be the start of a chunk, and returns its size.
  // "addr + size" is required to be the start of a new chunk, or the end
  // of the active area of the heap.
  virtual size_t block_size(const HeapWord* addr) const;

  // Requires "addr" to be the start of a block, and returns "TRUE" iff
  // the block is an object.
  virtual bool block_is_obj(const HeapWord* addr) const;

  // Does this heap support heap inspection? (+PrintClassHistogram)
  virtual bool supports_heap_inspection() const { return true; }

  // Section on thread-local allocation buffers (TLABs)
  // See CollectedHeap for semantics.

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  bool supports_tlab_allocation() const;
  size_t tlab_capacity(Thread* ignored) const;
  size_t tlab_used(Thread* ignored) const;
  size_t max_tlab_size() const;
  size_t unsafe_max_tlab_alloc(Thread* ignored) const;
1453 1454 1455

  // Can a compiler initialize a new object without store barriers?
  // This permission only extends from the creation of a new object
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  // via a TLAB up to the first subsequent safepoint. If such permission
  // is granted for this heap type, the compiler promises to call
  // defer_store_barrier() below on any slow path allocation of
  // a new object for which such initializing store barriers will
  // have been elided. G1, like CMS, allows this, but should be
  // ready to provide a compensating write barrier as necessary
  // if that storage came out of a non-young region. The efficiency
  // of this implementation depends crucially on being able to
  // answer very efficiently in constant time whether a piece of
  // storage in the heap comes from a young region or not.
  // See ReduceInitialCardMarks.
1467
  virtual bool can_elide_tlab_store_barriers() const {
1468
    return true;
1469 1470
  }

1471 1472 1473 1474
  virtual bool card_mark_must_follow_store() const {
    return true;
  }

1475
  inline bool is_in_young(const oop obj);
1476

1477 1478 1479 1480 1481 1482
#ifdef ASSERT
  virtual bool is_in_partial_collection(const void* p);
#endif

  virtual bool is_scavengable(const void* addr);

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  // We don't need barriers for initializing stores to objects
  // in the young gen: for the SATB pre-barrier, there is no
  // pre-value that needs to be remembered; for the remembered-set
  // update logging post-barrier, we don't maintain remembered set
1487
  // information for young gen objects.
1488
  virtual inline bool can_elide_initializing_store_barrier(oop new_obj);
1489 1490 1491

  // Returns "true" iff the given word_size is "very large".
  static bool isHumongous(size_t word_size) {
1492 1493 1494 1495 1496 1497
    // Note this has to be strictly greater-than as the TLABs
    // are capped at the humongous thresold and we want to
    // ensure that we don't try to allocate a TLAB as
    // humongous and that we don't allocate a humongous
    // object in a TLAB.
    return word_size > _humongous_object_threshold_in_words;
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  }

  // Update mod union table with the set of dirty cards.
  void updateModUnion();

  // Set the mod union bits corresponding to the given memRegion.  Note
  // that this is always a safe operation, since it doesn't clear any
  // bits.
  void markModUnionRange(MemRegion mr);

  // Records the fact that a marking phase is no longer in progress.
  void set_marking_complete() {
    _mark_in_progress = false;
  }
  void set_marking_started() {
    _mark_in_progress = true;
  }
  bool mark_in_progress() {
    return _mark_in_progress;
  }

  // Print the maximum heap capacity.
  virtual size_t max_capacity() const;

  virtual jlong millis_since_last_gc();

1524

1525 1526 1527 1528 1529 1530 1531
  // Convenience function to be used in situations where the heap type can be
  // asserted to be this type.
  static G1CollectedHeap* heap();

  void set_region_short_lived_locked(HeapRegion* hr);
  // add appropriate methods for any other surv rate groups

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  YoungList* young_list() const { return _young_list; }
1533 1534 1535 1536 1537

  // debugging
  bool check_young_list_well_formed() {
    return _young_list->check_list_well_formed();
  }
1538 1539

  bool check_young_list_empty(bool check_heap,
1540 1541 1542 1543 1544 1545 1546 1547 1548 1549 1550 1551 1552 1553 1554 1555 1556 1557 1558 1559 1560 1561 1562 1563 1564 1565 1566 1567 1568 1569 1570 1571 1572 1573 1574 1575 1576 1577 1578 1579 1580 1581
                              bool check_sample = true);

  // *** Stuff related to concurrent marking.  It's not clear to me that so
  // many of these need to be public.

  // The functions below are helper functions that a subclass of
  // "CollectedHeap" can use in the implementation of its virtual
  // functions.
  // This performs a concurrent marking of the live objects in a
  // bitmap off to the side.
  void doConcurrentMark();

  bool isMarkedPrev(oop obj) const;
  bool isMarkedNext(oop obj) const;

  // Determine if an object is dead, given the object and also
  // the region to which the object belongs. An object is dead
  // iff a) it was not allocated since the last mark and b) it
  // is not marked.

  bool is_obj_dead(const oop obj, const HeapRegion* hr) const {
    return
      !hr->obj_allocated_since_prev_marking(obj) &&
      !isMarkedPrev(obj);
  }

  // This function returns true when an object has been
  // around since the previous marking and hasn't yet
  // been marked during this marking.

  bool is_obj_ill(const oop obj, const HeapRegion* hr) const {
    return
      !hr->obj_allocated_since_next_marking(obj) &&
      !isMarkedNext(obj);
  }

  // Determine if an object is dead, given only the object itself.
  // This will find the region to which the object belongs and
  // then call the region version of the same function.

  // Added if it is NULL it isn't dead.

1582
  inline bool is_obj_dead(const oop obj) const;
1583

1584
  inline bool is_obj_ill(const oop obj) const;
1585

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  bool allocated_since_marking(oop obj, HeapRegion* hr, VerifyOption vo);
  HeapWord* top_at_mark_start(HeapRegion* hr, VerifyOption vo);
  bool is_marked(oop obj, VerifyOption vo);
  const char* top_at_mark_start_str(VerifyOption vo);

  ConcurrentMark* concurrent_mark() const { return _cm; }

  // Refinement

  ConcurrentG1Refine* concurrent_g1_refine() const { return _cg1r; }

  // The dirty cards region list is used to record a subset of regions
  // whose cards need clearing. The list if populated during the
  // remembered set scanning and drained during the card table
  // cleanup. Although the methods are reentrant, population/draining
  // phases must not overlap. For synchronization purposes the last
  // element on the list points to itself.
  HeapRegion* _dirty_cards_region_list;
  void push_dirty_cards_region(HeapRegion* hr);
  HeapRegion* pop_dirty_cards_region();

  // Optimized nmethod scanning support routines

  // Register the given nmethod with the G1 heap
  virtual void register_nmethod(nmethod* nm);

  // Unregister the given nmethod from the G1 heap
  virtual void unregister_nmethod(nmethod* nm);

  // Migrate the nmethods in the code root lists of the regions
  // in the collection set to regions in to-space. In the event
  // of an evacuation failure, nmethods that reference objects
  // that were not successfullly evacuated are not migrated.
  void migrate_strong_code_roots();

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  // Free up superfluous code root memory.
  void purge_code_root_memory();

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  // During an initial mark pause, mark all the code roots that
  // point into regions *not* in the collection set.
  void mark_strong_code_roots(uint worker_id);

  // Rebuild the stong code root lists for each region
  // after a full GC
  void rebuild_strong_code_roots();

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  // Delete entries for dead interned string and clean up unreferenced symbols
  // in symbol table, possibly in parallel.
  void unlink_string_and_symbol_table(BoolObjectClosure* is_alive, bool unlink_strings = true, bool unlink_symbols = true);

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  // Redirty logged cards in the refinement queue.
  void redirty_logged_cards();
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  // Verification

  // The following is just to alert the verification code
  // that a full collection has occurred and that the
  // remembered sets are no longer up to date.
  bool _full_collection;
  void set_full_collection() { _full_collection = true;}
  void clear_full_collection() {_full_collection = false;}
  bool full_collection() {return _full_collection;}

  // Perform any cleanup actions necessary before allowing a verification.
  virtual void prepare_for_verify();

  // Perform verification.

  // vo == UsePrevMarking  -> use "prev" marking information,
  // vo == UseNextMarking -> use "next" marking information
  // vo == UseMarkWord    -> use the mark word in the object header
  //
  // NOTE: Only the "prev" marking information is guaranteed to be
  // consistent most of the time, so most calls to this should use
  // vo == UsePrevMarking.
  // Currently, there is only one case where this is called with
  // vo == UseNextMarking, which is to verify the "next" marking
  // information at the end of remark.
  // Currently there is only one place where this is called with
  // vo == UseMarkWord, which is to verify the marking during a
  // full GC.
  void verify(bool silent, VerifyOption vo);

  // Override; it uses the "prev" marking information
  virtual void verify(bool silent);

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  // The methods below are here for convenience and dispatch the
  // appropriate method depending on value of the given VerifyOption
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  // parameter. The values for that parameter, and their meanings,
  // are the same as those above.
1675 1676 1677

  bool is_obj_dead_cond(const oop obj,
                        const HeapRegion* hr,
1678
                        const VerifyOption vo) const;
1679 1680

  bool is_obj_dead_cond(const oop obj,
1681
                        const VerifyOption vo) const;
1682

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  // Printing
1684

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  virtual void print_on(outputStream* st) const;
  virtual void print_extended_on(outputStream* st) const;
  virtual void print_on_error(outputStream* st) const;
1688

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  virtual void print_gc_threads_on(outputStream* st) const;
  virtual void gc_threads_do(ThreadClosure* tc) const;
1691

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  // Override
  void print_tracing_info() const;

  // The following two methods are helpful for debugging RSet issues.
  void print_cset_rsets() PRODUCT_RETURN;
  void print_all_rsets() PRODUCT_RETURN;
1698

1699 1700 1701 1702 1703 1704 1705 1706 1707 1708
public:
  void stop_conc_gc_threads();

  size_t pending_card_num();
  size_t cards_scanned();

protected:
  size_t _max_heap_capacity;
};

1709 1710 1711 1712 1713
class G1ParGCAllocBuffer: public ParGCAllocBuffer {
private:
  bool        _retired;

public:
1714
  G1ParGCAllocBuffer(size_t gclab_word_size);
1715

1716
  void set_buf(HeapWord* buf) {
1717 1718 1719 1720
    ParGCAllocBuffer::set_buf(buf);
    _retired = false;
  }

1721
  void retire(bool end_of_gc, bool retain) {
1722 1723 1724 1725 1726 1727 1728 1729 1730 1731 1732 1733
    if (_retired)
      return;
    ParGCAllocBuffer::retire(end_of_gc, retain);
    _retired = true;
  }
};

class G1ParScanThreadState : public StackObj {
protected:
  G1CollectedHeap* _g1h;
  RefToScanQueue*  _refs;
  DirtyCardQueue   _dcq;
1734
  G1SATBCardTableModRefBS* _ct_bs;
1735 1736
  G1RemSet* _g1_rem;

1737 1738 1739
  G1ParGCAllocBuffer  _surviving_alloc_buffer;
  G1ParGCAllocBuffer  _tenured_alloc_buffer;
  G1ParGCAllocBuffer* _alloc_buffers[GCAllocPurposeCount];
1740
  ageTable            _age_table;
1741

1742 1743
  G1ParScanClosure    _scanner;

1744 1745 1746 1747 1748
  size_t           _alloc_buffer_waste;
  size_t           _undo_waste;

  OopsInHeapRegionClosure*      _evac_failure_cl;

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  int  _hash_seed;
1750
  uint _queue_num;
1751

1752
  size_t _term_attempts;
1753 1754 1755 1756 1757 1758 1759 1760 1761 1762 1763 1764 1765

  double _start;
  double _start_strong_roots;
  double _strong_roots_time;
  double _start_term;
  double _term_time;

  // Map from young-age-index (0 == not young, 1 is youngest) to
  // surviving words. base is what we get back from the malloc call
  size_t* _surviving_young_words_base;
  // this points into the array, as we use the first few entries for padding
  size_t* _surviving_young_words;

1766
#define PADDING_ELEM_NUM (DEFAULT_CACHE_LINE_SIZE / sizeof(size_t))
1767 1768 1769 1770 1771 1772

  void   add_to_alloc_buffer_waste(size_t waste) { _alloc_buffer_waste += waste; }

  void   add_to_undo_waste(size_t waste)         { _undo_waste += waste; }

  DirtyCardQueue& dirty_card_queue()             { return _dcq;  }
1773
  G1SATBCardTableModRefBS* ctbs()                { return _ct_bs; }
1774

1775
  template <class T> inline void immediate_rs_update(HeapRegion* from, T* p, int tid);
1776 1777 1778 1779 1780 1781 1782 1783 1784 1785 1786 1787 1788 1789

  template <class T> void deferred_rs_update(HeapRegion* from, T* p, int tid) {
    // If the new value of the field points to the same region or
    // is the to-space, we don't need to include it in the Rset updates.
    if (!from->is_in_reserved(oopDesc::load_decode_heap_oop(p)) && !from->is_survivor()) {
      size_t card_index = ctbs()->index_for(p);
      // If the card hasn't been added to the buffer, do it.
      if (ctbs()->mark_card_deferred(card_index)) {
        dirty_card_queue().enqueue((jbyte*)ctbs()->byte_for_index(card_index));
      }
    }
  }

public:
1790
  G1ParScanThreadState(G1CollectedHeap* g1h, uint queue_num, ReferenceProcessor* rp);
1791 1792

  ~G1ParScanThreadState() {
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    FREE_C_HEAP_ARRAY(size_t, _surviving_young_words_base, mtGC);
1794 1795 1796 1797 1798
  }

  RefToScanQueue*   refs()            { return _refs;             }
  ageTable*         age_table()       { return &_age_table;       }

1799
  G1ParGCAllocBuffer* alloc_buffer(GCAllocPurpose purpose) {
1800
    return _alloc_buffers[purpose];
1801 1802
  }

1803 1804
  size_t alloc_buffer_waste() const              { return _alloc_buffer_waste; }
  size_t undo_waste() const                      { return _undo_waste; }
1805 1806

#ifdef ASSERT
1807 1808 1809 1810
  bool verify_ref(narrowOop* ref) const;
  bool verify_ref(oop* ref) const;
  bool verify_task(StarTask ref) const;
#endif // ASSERT
1811

1812 1813 1814
  template <class T> void push_on_queue(T* ref) {
    assert(verify_ref(ref), "sanity");
    refs()->push(ref);
1815 1816
  }

1817
  template <class T> inline void update_rs(HeapRegion* from, T* p, int tid);
1818 1819 1820

  HeapWord* allocate_slow(GCAllocPurpose purpose, size_t word_sz) {
    HeapWord* obj = NULL;
1821 1822
    size_t gclab_word_size = _g1h->desired_plab_sz(purpose);
    if (word_sz * 100 < gclab_word_size * ParallelGCBufferWastePct) {
1823 1824 1825
      G1ParGCAllocBuffer* alloc_buf = alloc_buffer(purpose);
      add_to_alloc_buffer_waste(alloc_buf->words_remaining());
      alloc_buf->retire(false /* end_of_gc */, false /* retain */);
1826

1827
      HeapWord* buf = _g1h->par_allocate_during_gc(purpose, gclab_word_size);
1828
      if (buf == NULL) return NULL; // Let caller handle allocation failure.
1829 1830 1831
      // Otherwise.
      alloc_buf->set_word_size(gclab_word_size);
      alloc_buf->set_buf(buf);
1832 1833 1834 1835 1836 1837 1838 1839 1840 1841 1842 1843 1844 1845 1846 1847 1848 1849 1850 1851 1852 1853 1854 1855 1856 1857 1858 1859 1860 1861 1862 1863 1864 1865

      obj = alloc_buf->allocate(word_sz);
      assert(obj != NULL, "buffer was definitely big enough...");
    } else {
      obj = _g1h->par_allocate_during_gc(purpose, word_sz);
    }
    return obj;
  }

  HeapWord* allocate(GCAllocPurpose purpose, size_t word_sz) {
    HeapWord* obj = alloc_buffer(purpose)->allocate(word_sz);
    if (obj != NULL) return obj;
    return allocate_slow(purpose, word_sz);
  }

  void undo_allocation(GCAllocPurpose purpose, HeapWord* obj, size_t word_sz) {
    if (alloc_buffer(purpose)->contains(obj)) {
      assert(alloc_buffer(purpose)->contains(obj + word_sz - 1),
             "should contain whole object");
      alloc_buffer(purpose)->undo_allocation(obj, word_sz);
    } else {
      CollectedHeap::fill_with_object(obj, word_sz);
      add_to_undo_waste(word_sz);
    }
  }

  void set_evac_failure_closure(OopsInHeapRegionClosure* evac_failure_cl) {
    _evac_failure_cl = evac_failure_cl;
  }
  OopsInHeapRegionClosure* evac_failure_closure() {
    return _evac_failure_cl;
  }

  int* hash_seed() { return &_hash_seed; }
1866
  uint queue_num() { return _queue_num; }
1867

1868
  size_t term_attempts() const  { return _term_attempts; }
1869
  void note_term_attempt() { _term_attempts++; }
1870 1871 1872 1873 1874 1875 1876

  void start_strong_roots() {
    _start_strong_roots = os::elapsedTime();
  }
  void end_strong_roots() {
    _strong_roots_time += (os::elapsedTime() - _start_strong_roots);
  }
1877
  double strong_roots_time() const { return _strong_roots_time; }
1878 1879 1880 1881 1882 1883 1884 1885

  void start_term_time() {
    note_term_attempt();
    _start_term = os::elapsedTime();
  }
  void end_term_time() {
    _term_time += (os::elapsedTime() - _start_term);
  }
1886
  double term_time() const { return _term_time; }
1887

1888
  double elapsed_time() const {
1889 1890 1891
    return os::elapsedTime() - _start;
  }

1892 1893 1894 1895 1896
  static void
    print_termination_stats_hdr(outputStream* const st = gclog_or_tty);
  void
    print_termination_stats(int i, outputStream* const st = gclog_or_tty) const;

1897 1898 1899 1900 1901 1902 1903 1904
  size_t* surviving_young_words() {
    // We add on to hide entry 0 which accumulates surviving words for
    // age -1 regions (i.e. non-young ones)
    return _surviving_young_words;
  }

  void retire_alloc_buffers() {
    for (int ap = 0; ap < GCAllocPurposeCount; ++ap) {
1905
      size_t waste = _alloc_buffers[ap]->words_remaining();
1906
      add_to_alloc_buffer_waste(waste);
1907 1908 1909
      _alloc_buffers[ap]->flush_stats_and_retire(_g1h->stats_for_purpose((GCAllocPurpose)ap),
                                                 true /* end_of_gc */,
                                                 false /* retain */);
1910 1911
    }
  }
1912 1913 1914 1915 1916 1917 1918 1919 1920 1921 1922 1923 1924 1925 1926 1927 1928 1929 1930 1931 1932 1933 1934 1935 1936 1937 1938 1939 1940
private:
  #define G1_PARTIAL_ARRAY_MASK 0x2

  inline bool has_partial_array_mask(oop* ref) const {
    return ((uintptr_t)ref & G1_PARTIAL_ARRAY_MASK) == G1_PARTIAL_ARRAY_MASK;
  }

  // We never encode partial array oops as narrowOop*, so return false immediately.
  // This allows the compiler to create optimized code when popping references from
  // the work queue.
  inline bool has_partial_array_mask(narrowOop* ref) const {
    assert(((uintptr_t)ref & G1_PARTIAL_ARRAY_MASK) != G1_PARTIAL_ARRAY_MASK, "Partial array oop reference encoded as narrowOop*");
    return false;
  }

  // Only implement set_partial_array_mask() for regular oops, not for narrowOops.
  // We always encode partial arrays as regular oop, to allow the
  // specialization for has_partial_array_mask() for narrowOops above.
  // This means that unintentional use of this method with narrowOops are caught
  // by the compiler.
  inline oop* set_partial_array_mask(oop obj) const {
    assert(((uintptr_t)(void *)obj & G1_PARTIAL_ARRAY_MASK) == 0, "Information loss!");
    return (oop*) ((uintptr_t)(void *)obj | G1_PARTIAL_ARRAY_MASK);
  }

  inline oop clear_partial_array_mask(oop* ref) const {
    return cast_to_oop((intptr_t)ref & ~G1_PARTIAL_ARRAY_MASK);
  }

1941
  inline void do_oop_partial_array(oop* p);
1942 1943 1944 1945 1946 1947 1948 1949 1950 1951 1952 1953 1954 1955 1956 1957 1958 1959 1960 1961 1962 1963 1964 1965 1966 1967

  // This method is applied to the fields of the objects that have just been copied.
  template <class T> void do_oop_evac(T* p, HeapRegion* from) {
    assert(!oopDesc::is_null(oopDesc::load_decode_heap_oop(p)),
           "Reference should not be NULL here as such are never pushed to the task queue.");
    oop obj = oopDesc::load_decode_heap_oop_not_null(p);

    // Although we never intentionally push references outside of the collection
    // set, due to (benign) races in the claim mechanism during RSet scanning more
    // than one thread might claim the same card. So the same card may be
    // processed multiple times. So redo this check.
    if (_g1h->in_cset_fast_test(obj)) {
      oop forwardee;
      if (obj->is_forwarded()) {
        forwardee = obj->forwardee();
      } else {
        forwardee = copy_to_survivor_space(obj);
      }
      assert(forwardee != NULL, "forwardee should not be NULL");
      oopDesc::encode_store_heap_oop(p, forwardee);
    }

    assert(obj != NULL, "Must be");
    update_rs(from, p, queue_num());
  }
public:
1968

1969 1970
  oop copy_to_survivor_space(oop const obj);

1971
  template <class T> inline void deal_with_reference(T* ref_to_scan);
1972

1973
  inline void deal_with_reference(StarTask ref);
1974

1975
public:
1976
  void trim_queue();
1977
};
1978 1979

#endif // SHARE_VM_GC_IMPLEMENTATION_G1_G1COLLECTEDHEAP_HPP