src/share/vm/gc_implementation/g1/heapRegionRemSet.hpp - platform/external/jetbrains/jdk8u_hotspot - Git at Google

 /*
  * Copyright (c) 2001, 2014, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  *
  */

 #ifndef SHARE_VM_GC_IMPLEMENTATION_G1_HEAPREGIONREMSET_HPP
 #define SHARE_VM_GC_IMPLEMENTATION_G1_HEAPREGIONREMSET_HPP

 #include "gc_implementation/g1/g1CodeCacheRemSet.hpp"
 #include "gc_implementation/g1/sparsePRT.hpp"

 // Remembered set for a heap region.  Represent a set of "cards" that
 // contain pointers into the owner heap region.  Cards are defined somewhat
 // abstractly, in terms of what the "BlockOffsetTable" in use can parse.

 class G1CollectedHeap;
 class G1BlockOffsetSharedArray;
 class HeapRegion;
 class HeapRegionRemSetIterator;
 class PerRegionTable;
 class SparsePRT;
 class nmethod;

 // Essentially a wrapper around SparsePRTCleanupTask. See
 // sparsePRT.hpp for more details.
 class HRRSCleanupTask : public SparsePRTCleanupTask {
 };

 // The FromCardCache remembers the most recently processed card on the heap on
 // a per-region and per-thread basis.
 class FromCardCache : public AllStatic {
  private:
   // Array of card indices. Indexed by thread X and heap region to minimize
   // thread contention.
   static int** _cache;
   static uint _max_regions;
   static size_t _static_mem_size;

  public:
   enum {
     InvalidCard = -1 // Card value of an invalid card, i.e. a card index not otherwise used.
   };

   static void clear(uint region_idx);

   // Returns true if the given card is in the cache at the given location, or
   // replaces the card at that location and returns false.
   static bool contains_or_replace(uint worker_id, uint region_idx, int card) {
     int card_in_cache = at(worker_id, region_idx);
     if (card_in_cache == card) {
       return true;
     } else {
       set(worker_id, region_idx, card);
       return false;
     }
   }

   static int at(uint worker_id, uint region_idx) {
     return _cache[worker_id][region_idx];
   }

   static void set(uint worker_id, uint region_idx, int val) {
     _cache[worker_id][region_idx] = val;
   }

   static void initialize(uint n_par_rs, uint max_num_regions);

   static void invalidate(uint start_idx, size_t num_regions);

   static void print(outputStream* out = gclog_or_tty) PRODUCT_RETURN;

   static size_t static_mem_size() {
     return _static_mem_size;
   }
 };

 // The "_coarse_map" is a bitmap with one bit for each region, where set
 // bits indicate that the corresponding region may contain some pointer
 // into the owning region.

 // The "_fine_grain_entries" array is an open hash table of PerRegionTables
 // (PRTs), indicating regions for which we're keeping the RS as a set of
 // cards.  The strategy is to cap the size of the fine-grain table,
 // deleting an entry and setting the corresponding coarse-grained bit when
 // we would overflow this cap.

 // We use a mixture of locking and lock-free techniques here.  We allow
 // threads to locate PRTs without locking, but threads attempting to alter
 // a bucket list obtain a lock.  This means that any failing attempt to
 // find a PRT must be retried with the lock.  It might seem dangerous that
 // a read can find a PRT that is concurrently deleted.  This is all right,
 // because:
 //
 //   1) We only actually free PRT's at safe points (though we reuse them at
 //      other times).
 //   2) We find PRT's in an attempt to add entries.  If a PRT is deleted,
 //      it's _coarse_map bit is set, so the that we were attempting to add
 //      is represented.  If a deleted PRT is re-used, a thread adding a bit,
 //      thinking the PRT is for a different region, does no harm.

 class OtherRegionsTable VALUE_OBJ_CLASS_SPEC {
   friend class HeapRegionRemSetIterator;

   G1CollectedHeap* _g1h;
   Mutex*           _m;
   HeapRegion*      _hr;

   // These are protected by "_m".
   BitMap      _coarse_map;
   size_t      _n_coarse_entries;
   static jint _n_coarsenings;

   PerRegionTable** _fine_grain_regions;
   size_t           _n_fine_entries;

   // The fine grain remembered sets are doubly linked together using
   // their 'next' and 'prev' fields.
   // This allows fast bulk freeing of all the fine grain remembered
   // set entries, and fast finding of all of them without iterating
   // over the _fine_grain_regions table.
   PerRegionTable * _first_all_fine_prts;
   PerRegionTable * _last_all_fine_prts;

   // Used to sample a subset of the fine grain PRTs to determine which
   // PRT to evict and coarsen.
   size_t        _fine_eviction_start;
   static size_t _fine_eviction_stride;
   static size_t _fine_eviction_sample_size;

   SparsePRT   _sparse_table;

   // These are static after init.
   static size_t _max_fine_entries;
   static size_t _mod_max_fine_entries_mask;

   // Requires "prt" to be the first element of the bucket list appropriate
   // for "hr".  If this list contains an entry for "hr", return it,
   // otherwise return "NULL".
   PerRegionTable* find_region_table(size_t ind, HeapRegion* hr) const;

   // Find, delete, and return a candidate PerRegionTable, if any exists,
   // adding the deleted region to the coarse bitmap.  Requires the caller
   // to hold _m, and the fine-grain table to be full.
   PerRegionTable* delete_region_table();

   // If a PRT for "hr" is in the bucket list indicated by "ind" (which must
   // be the correct index for "hr"), delete it and return true; else return
   // false.
   bool del_single_region_table(size_t ind, HeapRegion* hr);

   // link/add the given fine grain remembered set into the "all" list
   void link_to_all(PerRegionTable * prt);
   // unlink/remove the given fine grain remembered set into the "all" list
   void unlink_from_all(PerRegionTable * prt);

 public:
   OtherRegionsTable(HeapRegion* hr, Mutex* m);

   HeapRegion* hr() const { return _hr; }

   // For now.  Could "expand" some tables in the future, so that this made
   // sense.
   void add_reference(OopOrNarrowOopStar from, int tid);

   // Returns whether this remembered set (and all sub-sets) have an occupancy
   // that is less or equal than the given occupancy.
   bool occupancy_less_or_equal_than(size_t limit) const;

   // Removes any entries shown by the given bitmaps to contain only dead
   // objects.
   void scrub(CardTableModRefBS* ctbs, BitMap* region_bm, BitMap* card_bm);

   // Returns whether this remembered set (and all sub-sets) contain no entries.
   bool is_empty() const;

   size_t occupied() const;
   size_t occ_fine() const;
   size_t occ_coarse() const;
   size_t occ_sparse() const;

   static jint n_coarsenings() { return _n_coarsenings; }

   // Returns size in bytes.
   // Not const because it takes a lock.
   size_t mem_size() const;
   static size_t static_mem_size();
   static size_t fl_mem_size();

   bool contains_reference(OopOrNarrowOopStar from) const;
   bool contains_reference_locked(OopOrNarrowOopStar from) const;

   void clear();

   // Specifically clear the from_card_cache.
   void clear_fcc();

   void do_cleanup_work(HRRSCleanupTask* hrrs_cleanup_task);

   // Declare the heap size (in # of regions) to the OtherRegionsTable.
   // (Uses it to initialize from_card_cache).
   static void initialize(uint max_regions);

   // Declares that regions between start_idx <= i < start_idx + num_regions are
   // not in use. Make sure that any entries for these regions are invalid.
   static void invalidate(uint start_idx, size_t num_regions);

   static void print_from_card_cache();
 };

 class HeapRegionRemSet : public CHeapObj<mtGC> {
   friend class VMStructs;
   friend class HeapRegionRemSetIterator;

 public:
   enum Event {
     Event_EvacStart, Event_EvacEnd, Event_RSUpdateEnd, Event_illegal
   };

 private:
   G1BlockOffsetSharedArray* _bosa;
   G1BlockOffsetSharedArray* bosa() const { return _bosa; }

   // A set of code blobs (nmethods) whose code contains pointers into
   // the region that owns this RSet.
   G1CodeRootSet _code_roots;

   Mutex _m;

   OtherRegionsTable _other_regions;

   enum ParIterState { Unclaimed, Claimed, Complete };
   volatile ParIterState _iter_state;
   volatile jlong _iter_claimed;

   // Unused unless G1RecordHRRSOops is true.

   static const int MaxRecorded = 1000000;
   static OopOrNarrowOopStar* _recorded_oops;
   static HeapWord**          _recorded_cards;
   static HeapRegion**        _recorded_regions;
   static int                 _n_recorded;

   static const int MaxRecordedEvents = 1000;
   static Event*       _recorded_events;
   static int*         _recorded_event_index;
   static int          _n_recorded_events;

   static void print_event(outputStream* str, Event evnt);

 public:
   HeapRegionRemSet(G1BlockOffsetSharedArray* bosa, HeapRegion* hr);

   static uint num_par_rem_sets();
   static void setup_remset_size();

   HeapRegion* hr() const {
     return _other_regions.hr();
   }

   bool is_empty() const {
     return (strong_code_roots_list_length() == 0) && _other_regions.is_empty();
   }

   bool occupancy_less_or_equal_than(size_t occ) const {
     return (strong_code_roots_list_length() == 0) && _other_regions.occupancy_less_or_equal_than(occ);
   }

   size_t occupied() {
     MutexLockerEx x(&_m, Mutex::_no_safepoint_check_flag);
     return occupied_locked();
   }
   size_t occupied_locked() {
     return _other_regions.occupied();
   }
   size_t occ_fine() const {
     return _other_regions.occ_fine();
   }
   size_t occ_coarse() const {
     return _other_regions.occ_coarse();
   }
   size_t occ_sparse() const {
     return _other_regions.occ_sparse();
   }

   static jint n_coarsenings() { return OtherRegionsTable::n_coarsenings(); }

   // Used in the sequential case.
   void add_reference(OopOrNarrowOopStar from) {
     _other_regions.add_reference(from, 0);
   }

   // Used in the parallel case.
   void add_reference(OopOrNarrowOopStar from, int tid) {
     _other_regions.add_reference(from, tid);
   }

   // Removes any entries shown by the given bitmaps to contain only dead
   // objects.
   void scrub(CardTableModRefBS* ctbs, BitMap* region_bm, BitMap* card_bm);

   // The region is being reclaimed; clear its remset, and any mention of
   // entries for this region in other remsets.
   void clear();
   void clear_locked();

   // Attempt to claim the region.  Returns true iff this call caused an
   // atomic transition from Unclaimed to Claimed.
   bool claim_iter();
   // Sets the iteration state to "complete".
   void set_iter_complete();
   // Returns "true" iff the region's iteration is complete.
   bool iter_is_complete();

   // Support for claiming blocks of cards during iteration
   size_t iter_claimed() const { return (size_t)_iter_claimed; }
   // Claim the next block of cards
   size_t iter_claimed_next(size_t step) {
     size_t current, next;
     do {
       current = iter_claimed();
       next = current + step;
     } while (Atomic::cmpxchg((jlong)next, &_iter_claimed, (jlong)current) != (jlong)current);
     return current;
   }
   void reset_for_par_iteration();

   bool verify_ready_for_par_iteration() {
     return (_iter_state == Unclaimed) && (_iter_claimed == 0);
   }

   // The actual # of bytes this hr_remset takes up.
   // Note also includes the strong code root set.
   size_t mem_size() {
     MutexLockerEx x(&_m, Mutex::_no_safepoint_check_flag);
     return _other_regions.mem_size()
       // This correction is necessary because the above includes the second
       // part.
       + (sizeof(HeapRegionRemSet) - sizeof(OtherRegionsTable))
       + strong_code_roots_mem_size();
   }

   // Returns the memory occupancy of all static data structures associated
   // with remembered sets.
   static size_t static_mem_size() {
     return OtherRegionsTable::static_mem_size() + G1CodeRootSet::static_mem_size();
   }

   // Returns the memory occupancy of all free_list data structures associated
   // with remembered sets.
   static size_t fl_mem_size() {
     return OtherRegionsTable::fl_mem_size();
   }

   bool contains_reference(OopOrNarrowOopStar from) const {
     return _other_regions.contains_reference(from);
   }

   // Routines for managing the list of code roots that point into
   // the heap region that owns this RSet.
   void add_strong_code_root(nmethod* nm);
   void add_strong_code_root_locked(nmethod* nm);
   void remove_strong_code_root(nmethod* nm);

   // Applies blk->do_code_blob() to each of the entries in
   // the strong code roots list
   void strong_code_roots_do(CodeBlobClosure* blk) const;

   void clean_strong_code_roots(HeapRegion* hr);

   // Returns the number of elements in the strong code roots list
   size_t strong_code_roots_list_length() const {
     return _code_roots.length();
   }

   // Returns true if the strong code roots contains the given
   // nmethod.
   bool strong_code_roots_list_contains(nmethod* nm) {
     return _code_roots.contains(nm);
   }

   // Returns the amount of memory, in bytes, currently
   // consumed by the strong code roots.
   size_t strong_code_roots_mem_size();

   void print() PRODUCT_RETURN;

   // Called during a stop-world phase to perform any deferred cleanups.
   static void cleanup();

   // Declare the heap size (in # of regions) to the HeapRegionRemSet(s).
   // (Uses it to initialize from_card_cache).
   static void init_heap(uint max_regions) {
     OtherRegionsTable::initialize(max_regions);
   }

   static void invalidate(uint start_idx, uint num_regions) {
     OtherRegionsTable::invalidate(start_idx, num_regions);
   }

 #ifndef PRODUCT
   static void print_from_card_cache() {
     OtherRegionsTable::print_from_card_cache();
   }
 #endif

   static void record(HeapRegion* hr, OopOrNarrowOopStar f);
   static void print_recorded();
   static void record_event(Event evnt);

   // These are wrappers for the similarly-named methods on
   // SparsePRT. Look at sparsePRT.hpp for more details.
   static void reset_for_cleanup_tasks();
   void do_cleanup_work(HRRSCleanupTask* hrrs_cleanup_task);
   static void finish_cleanup_task(HRRSCleanupTask* hrrs_cleanup_task);

   // Run unit tests.
 #ifndef PRODUCT
   static void test_prt();
   static void test();
 #endif
 };

 class HeapRegionRemSetIterator : public StackObj {
  private:
   // The region RSet over which we are iterating.
   HeapRegionRemSet* _hrrs;

   // Local caching of HRRS fields.
   const BitMap*             _coarse_map;

   G1BlockOffsetSharedArray* _bosa;
   G1CollectedHeap*          _g1h;

   // The number of cards yielded since initialization.
   size_t _n_yielded_fine;
   size_t _n_yielded_coarse;
   size_t _n_yielded_sparse;

   // Indicates what granularity of table that we are currently iterating over.
   // We start iterating over the sparse table, progress to the fine grain
   // table, and then finish with the coarse table.
   enum IterState {
     Sparse,
     Fine,
     Coarse
   };
   IterState _is;

   // For both Coarse and Fine remembered set iteration this contains the
   // first card number of the heap region we currently iterate over.
   size_t _cur_region_card_offset;

   // Current region index for the Coarse remembered set iteration.
   int    _coarse_cur_region_index;
   size_t _coarse_cur_region_cur_card;

   bool coarse_has_next(size_t& card_index);

   // The PRT we are currently iterating over.
   PerRegionTable* _fine_cur_prt;
   // Card offset within the current PRT.
   size_t _cur_card_in_prt;

   // Update internal variables when switching to the given PRT.
   void switch_to_prt(PerRegionTable* prt);
   bool fine_has_next();
   bool fine_has_next(size_t& card_index);

   // The Sparse remembered set iterator.
   SparsePRTIter _sparse_iter;

  public:
   HeapRegionRemSetIterator(HeapRegionRemSet* hrrs);

   // If there remains one or more cards to be yielded, returns true and
   // sets "card_index" to one of those cards (which is then considered
   // yielded.)   Otherwise, returns false (and leaves "card_index"
   // undefined.)
   bool has_next(size_t& card_index);

   size_t n_yielded_fine() { return _n_yielded_fine; }
   size_t n_yielded_coarse() { return _n_yielded_coarse; }
   size_t n_yielded_sparse() { return _n_yielded_sparse; }
   size_t n_yielded() {
     return n_yielded_fine() + n_yielded_coarse() + n_yielded_sparse();
   }
 };

 #endif // SHARE_VM_GC_IMPLEMENTATION_G1_HEAPREGIONREMSET_HPP
	/*
	* Copyright (c) 2001, 2014, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*
	*/

	#ifndef SHARE_VM_GC_IMPLEMENTATION_G1_HEAPREGIONREMSET_HPP
	#define SHARE_VM_GC_IMPLEMENTATION_G1_HEAPREGIONREMSET_HPP

	#include "gc_implementation/g1/g1CodeCacheRemSet.hpp"
	#include "gc_implementation/g1/sparsePRT.hpp"

	// Remembered set for a heap region. Represent a set of "cards" that
	// contain pointers into the owner heap region. Cards are defined somewhat
	// abstractly, in terms of what the "BlockOffsetTable" in use can parse.

	class G1CollectedHeap;
	class G1BlockOffsetSharedArray;
	class HeapRegion;
	class HeapRegionRemSetIterator;
	class PerRegionTable;
	class SparsePRT;
	class nmethod;

	// Essentially a wrapper around SparsePRTCleanupTask. See
	// sparsePRT.hpp for more details.
	class HRRSCleanupTask : public SparsePRTCleanupTask {
	};

	// The FromCardCache remembers the most recently processed card on the heap on
	// a per-region and per-thread basis.
	class FromCardCache : public AllStatic {
	private:
	// Array of card indices. Indexed by thread X and heap region to minimize
	// thread contention.
	static int** _cache;
	static uint _max_regions;
	static size_t _static_mem_size;

	public:
	enum {
	InvalidCard = -1 // Card value of an invalid card, i.e. a card index not otherwise used.
	};

	static void clear(uint region_idx);

	// Returns true if the given card is in the cache at the given location, or
	// replaces the card at that location and returns false.
	static bool contains_or_replace(uint worker_id, uint region_idx, int card) {
	int card_in_cache = at(worker_id, region_idx);
	if (card_in_cache == card) {
	return true;
	} else {
	set(worker_id, region_idx, card);
	return false;
	}
	}

	static int at(uint worker_id, uint region_idx) {
	return _cache[worker_id][region_idx];
	}

	static void set(uint worker_id, uint region_idx, int val) {
	_cache[worker_id][region_idx] = val;
	}

	static void initialize(uint n_par_rs, uint max_num_regions);

	static void invalidate(uint start_idx, size_t num_regions);

	static void print(outputStream* out = gclog_or_tty) PRODUCT_RETURN;

	static size_t static_mem_size() {
	return _static_mem_size;
	}
	};

	// The "_coarse_map" is a bitmap with one bit for each region, where set
	// bits indicate that the corresponding region may contain some pointer
	// into the owning region.

	// The "_fine_grain_entries" array is an open hash table of PerRegionTables
	// (PRTs), indicating regions for which we're keeping the RS as a set of
	// cards. The strategy is to cap the size of the fine-grain table,
	// deleting an entry and setting the corresponding coarse-grained bit when
	// we would overflow this cap.

	// We use a mixture of locking and lock-free techniques here. We allow
	// threads to locate PRTs without locking, but threads attempting to alter
	// a bucket list obtain a lock. This means that any failing attempt to
	// find a PRT must be retried with the lock. It might seem dangerous that
	// a read can find a PRT that is concurrently deleted. This is all right,
	// because:
	//
	// 1) We only actually free PRT's at safe points (though we reuse them at
	// other times).
	// 2) We find PRT's in an attempt to add entries. If a PRT is deleted,
	// it's _coarse_map bit is set, so the that we were attempting to add
	// is represented. If a deleted PRT is re-used, a thread adding a bit,
	// thinking the PRT is for a different region, does no harm.

	class OtherRegionsTable VALUE_OBJ_CLASS_SPEC {
	friend class HeapRegionRemSetIterator;

	G1CollectedHeap* _g1h;
	Mutex* _m;
	HeapRegion* _hr;

	// These are protected by "_m".
	BitMap _coarse_map;
	size_t _n_coarse_entries;
	static jint _n_coarsenings;

	PerRegionTable** _fine_grain_regions;
	size_t _n_fine_entries;

	// The fine grain remembered sets are doubly linked together using
	// their 'next' and 'prev' fields.
	// This allows fast bulk freeing of all the fine grain remembered
	// set entries, and fast finding of all of them without iterating
	// over the _fine_grain_regions table.
	PerRegionTable * _first_all_fine_prts;
	PerRegionTable * _last_all_fine_prts;

	// Used to sample a subset of the fine grain PRTs to determine which
	// PRT to evict and coarsen.
	size_t _fine_eviction_start;
	static size_t _fine_eviction_stride;
	static size_t _fine_eviction_sample_size;

	SparsePRT _sparse_table;

	// These are static after init.
	static size_t _max_fine_entries;
	static size_t _mod_max_fine_entries_mask;

	// Requires "prt" to be the first element of the bucket list appropriate
	// for "hr". If this list contains an entry for "hr", return it,
	// otherwise return "NULL".
	PerRegionTable* find_region_table(size_t ind, HeapRegion* hr) const;

	// Find, delete, and return a candidate PerRegionTable, if any exists,
	// adding the deleted region to the coarse bitmap. Requires the caller
	// to hold _m, and the fine-grain table to be full.
	PerRegionTable* delete_region_table();

	// If a PRT for "hr" is in the bucket list indicated by "ind" (which must
	// be the correct index for "hr"), delete it and return true; else return
	// false.
	bool del_single_region_table(size_t ind, HeapRegion* hr);

	// link/add the given fine grain remembered set into the "all" list
	void link_to_all(PerRegionTable * prt);
	// unlink/remove the given fine grain remembered set into the "all" list
	void unlink_from_all(PerRegionTable * prt);

	public:
	OtherRegionsTable(HeapRegion* hr, Mutex* m);

	HeapRegion* hr() const { return _hr; }

	// For now. Could "expand" some tables in the future, so that this made
	// sense.
	void add_reference(OopOrNarrowOopStar from, int tid);

	// Returns whether this remembered set (and all sub-sets) have an occupancy
	// that is less or equal than the given occupancy.
	bool occupancy_less_or_equal_than(size_t limit) const;

	// Removes any entries shown by the given bitmaps to contain only dead
	// objects.
	void scrub(CardTableModRefBS* ctbs, BitMap* region_bm, BitMap* card_bm);

	// Returns whether this remembered set (and all sub-sets) contain no entries.
	bool is_empty() const;

	size_t occupied() const;
	size_t occ_fine() const;
	size_t occ_coarse() const;
	size_t occ_sparse() const;

	static jint n_coarsenings() { return _n_coarsenings; }

	// Returns size in bytes.
	// Not const because it takes a lock.
	size_t mem_size() const;
	static size_t static_mem_size();
	static size_t fl_mem_size();

	bool contains_reference(OopOrNarrowOopStar from) const;
	bool contains_reference_locked(OopOrNarrowOopStar from) const;

	void clear();

	// Specifically clear the from_card_cache.
	void clear_fcc();

	void do_cleanup_work(HRRSCleanupTask* hrrs_cleanup_task);

	// Declare the heap size (in # of regions) to the OtherRegionsTable.
	// (Uses it to initialize from_card_cache).
	static void initialize(uint max_regions);

	// Declares that regions between start_idx <= i < start_idx + num_regions are
	// not in use. Make sure that any entries for these regions are invalid.
	static void invalidate(uint start_idx, size_t num_regions);

	static void print_from_card_cache();
	};

	class HeapRegionRemSet : public CHeapObj<mtGC> {
	friend class VMStructs;
	friend class HeapRegionRemSetIterator;

	public:
	enum Event {
	Event_EvacStart, Event_EvacEnd, Event_RSUpdateEnd, Event_illegal
	};

	private:
	G1BlockOffsetSharedArray* _bosa;
	G1BlockOffsetSharedArray* bosa() const { return _bosa; }

	// A set of code blobs (nmethods) whose code contains pointers into
	// the region that owns this RSet.
	G1CodeRootSet _code_roots;

	Mutex _m;

	OtherRegionsTable _other_regions;

	enum ParIterState { Unclaimed, Claimed, Complete };
	volatile ParIterState _iter_state;
	volatile jlong _iter_claimed;

	// Unused unless G1RecordHRRSOops is true.

	static const int MaxRecorded = 1000000;
	static OopOrNarrowOopStar* _recorded_oops;
	static HeapWord** _recorded_cards;
	static HeapRegion** _recorded_regions;
	static int _n_recorded;

	static const int MaxRecordedEvents = 1000;
	static Event* _recorded_events;
	static int* _recorded_event_index;
	static int _n_recorded_events;

	static void print_event(outputStream* str, Event evnt);

	public:
	HeapRegionRemSet(G1BlockOffsetSharedArray* bosa, HeapRegion* hr);

	static uint num_par_rem_sets();
	static void setup_remset_size();

	HeapRegion* hr() const {
	return _other_regions.hr();
	}

	bool is_empty() const {
	return (strong_code_roots_list_length() == 0) && _other_regions.is_empty();
	}

	bool occupancy_less_or_equal_than(size_t occ) const {
	return (strong_code_roots_list_length() == 0) && _other_regions.occupancy_less_or_equal_than(occ);
	}

	size_t occupied() {
	MutexLockerEx x(&_m, Mutex::_no_safepoint_check_flag);
	return occupied_locked();
	}
	size_t occupied_locked() {
	return _other_regions.occupied();
	}
	size_t occ_fine() const {
	return _other_regions.occ_fine();
	}
	size_t occ_coarse() const {
	return _other_regions.occ_coarse();
	}
	size_t occ_sparse() const {
	return _other_regions.occ_sparse();
	}

	static jint n_coarsenings() { return OtherRegionsTable::n_coarsenings(); }

	// Used in the sequential case.
	void add_reference(OopOrNarrowOopStar from) {
	_other_regions.add_reference(from, 0);
	}

	// Used in the parallel case.
	void add_reference(OopOrNarrowOopStar from, int tid) {
	_other_regions.add_reference(from, tid);
	}

	// Removes any entries shown by the given bitmaps to contain only dead
	// objects.
	void scrub(CardTableModRefBS* ctbs, BitMap* region_bm, BitMap* card_bm);

	// The region is being reclaimed; clear its remset, and any mention of
	// entries for this region in other remsets.
	void clear();
	void clear_locked();

	// Attempt to claim the region. Returns true iff this call caused an
	// atomic transition from Unclaimed to Claimed.
	bool claim_iter();
	// Sets the iteration state to "complete".
	void set_iter_complete();
	// Returns "true" iff the region's iteration is complete.
	bool iter_is_complete();

	// Support for claiming blocks of cards during iteration
	size_t iter_claimed() const { return (size_t)_iter_claimed; }
	// Claim the next block of cards
	size_t iter_claimed_next(size_t step) {
	size_t current, next;
	do {
	current = iter_claimed();
	next = current + step;
	} while (Atomic::cmpxchg((jlong)next, &_iter_claimed, (jlong)current) != (jlong)current);
	return current;
	}
	void reset_for_par_iteration();

	bool verify_ready_for_par_iteration() {
	return (_iter_state == Unclaimed) && (_iter_claimed == 0);
	}

	// The actual # of bytes this hr_remset takes up.
	// Note also includes the strong code root set.
	size_t mem_size() {
	MutexLockerEx x(&_m, Mutex::_no_safepoint_check_flag);
	return _other_regions.mem_size()
	// This correction is necessary because the above includes the second
	// part.
	+ (sizeof(HeapRegionRemSet) - sizeof(OtherRegionsTable))
	+ strong_code_roots_mem_size();
	}

	// Returns the memory occupancy of all static data structures associated
	// with remembered sets.
	static size_t static_mem_size() {
	return OtherRegionsTable::static_mem_size() + G1CodeRootSet::static_mem_size();
	}

	// Returns the memory occupancy of all free_list data structures associated
	// with remembered sets.
	static size_t fl_mem_size() {
	return OtherRegionsTable::fl_mem_size();
	}

	bool contains_reference(OopOrNarrowOopStar from) const {
	return _other_regions.contains_reference(from);
	}

	// Routines for managing the list of code roots that point into
	// the heap region that owns this RSet.
	void add_strong_code_root(nmethod* nm);
	void add_strong_code_root_locked(nmethod* nm);
	void remove_strong_code_root(nmethod* nm);

	// Applies blk->do_code_blob() to each of the entries in
	// the strong code roots list
	void strong_code_roots_do(CodeBlobClosure* blk) const;

	void clean_strong_code_roots(HeapRegion* hr);

	// Returns the number of elements in the strong code roots list
	size_t strong_code_roots_list_length() const {
	return _code_roots.length();
	}

	// Returns true if the strong code roots contains the given
	// nmethod.
	bool strong_code_roots_list_contains(nmethod* nm) {
	return _code_roots.contains(nm);
	}

	// Returns the amount of memory, in bytes, currently
	// consumed by the strong code roots.
	size_t strong_code_roots_mem_size();

	void print() PRODUCT_RETURN;

	// Called during a stop-world phase to perform any deferred cleanups.
	static void cleanup();

	// Declare the heap size (in # of regions) to the HeapRegionRemSet(s).
	// (Uses it to initialize from_card_cache).
	static void init_heap(uint max_regions) {
	OtherRegionsTable::initialize(max_regions);
	}

	static void invalidate(uint start_idx, uint num_regions) {
	OtherRegionsTable::invalidate(start_idx, num_regions);
	}

	#ifndef PRODUCT
	static void print_from_card_cache() {
	OtherRegionsTable::print_from_card_cache();
	}
	#endif

	static void record(HeapRegion* hr, OopOrNarrowOopStar f);
	static void print_recorded();
	static void record_event(Event evnt);

	// These are wrappers for the similarly-named methods on
	// SparsePRT. Look at sparsePRT.hpp for more details.
	static void reset_for_cleanup_tasks();
	void do_cleanup_work(HRRSCleanupTask* hrrs_cleanup_task);
	static void finish_cleanup_task(HRRSCleanupTask* hrrs_cleanup_task);

	// Run unit tests.
	#ifndef PRODUCT
	static void test_prt();
	static void test();
	#endif
	};

	class HeapRegionRemSetIterator : public StackObj {
	private:
	// The region RSet over which we are iterating.
	HeapRegionRemSet* _hrrs;

	// Local caching of HRRS fields.
	const BitMap* _coarse_map;

	G1BlockOffsetSharedArray* _bosa;
	G1CollectedHeap* _g1h;

	// The number of cards yielded since initialization.
	size_t _n_yielded_fine;
	size_t _n_yielded_coarse;
	size_t _n_yielded_sparse;

	// Indicates what granularity of table that we are currently iterating over.
	// We start iterating over the sparse table, progress to the fine grain
	// table, and then finish with the coarse table.
	enum IterState {
	Sparse,
	Fine,
	Coarse
	};
	IterState _is;

	// For both Coarse and Fine remembered set iteration this contains the
	// first card number of the heap region we currently iterate over.
	size_t _cur_region_card_offset;

	// Current region index for the Coarse remembered set iteration.
	int _coarse_cur_region_index;
	size_t _coarse_cur_region_cur_card;

	bool coarse_has_next(size_t& card_index);

	// The PRT we are currently iterating over.
	PerRegionTable* _fine_cur_prt;
	// Card offset within the current PRT.
	size_t _cur_card_in_prt;

	// Update internal variables when switching to the given PRT.
	void switch_to_prt(PerRegionTable* prt);
	bool fine_has_next();
	bool fine_has_next(size_t& card_index);

	// The Sparse remembered set iterator.
	SparsePRTIter _sparse_iter;

	public:
	HeapRegionRemSetIterator(HeapRegionRemSet* hrrs);

	// If there remains one or more cards to be yielded, returns true and
	// sets "card_index" to one of those cards (which is then considered
	// yielded.) Otherwise, returns false (and leaves "card_index"
	// undefined.)
	bool has_next(size_t& card_index);

	size_t n_yielded_fine() { return _n_yielded_fine; }
	size_t n_yielded_coarse() { return _n_yielded_coarse; }
	size_t n_yielded_sparse() { return _n_yielded_sparse; }
	size_t n_yielded() {
	return n_yielded_fine() + n_yielded_coarse() + n_yielded_sparse();
	}
	};

	#endif // SHARE_VM_GC_IMPLEMENTATION_G1_HEAPREGIONREMSET_HPP