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 /*

  * Copyright (c) 2001, 2010, 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.

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  */

 #ifndef SHARE_VM_MEMORY_ADAPTIVEFREELIST_HPP

 #define SHARE_VM_MEMORY_ADAPTIVEFREELIST_HPP

 #include "memory/freeList.hpp"

 #include "gc_implementation/shared/allocationStats.hpp"

 class CompactibleFreeListSpace;

 // A class for maintaining a free list of Chunk's.  The FreeList

 // maintains a the structure of the list (head, tail, etc.) plus

 // statistics for allocations from the list.  The links between items

 // are not part of FreeList.  The statistics are

 // used to make decisions about coalescing Chunk's when they

 // are swept during collection.

 //

 // See the corresponding .cpp file for a description of the specifics

 // for that implementation.

 class Mutex;

 template <class Chunk>

 class AdaptiveFreeList : public FreeList<Chunk> {

   friend class CompactibleFreeListSpace;

   friend class VMStructs;

   // friend class PrintTreeCensusClosure<Chunk, FreeList_t>;

   size_t        _hint;          // next larger size list with a positive surplus

   AllocationStats _allocation_stats; // allocation-related statistics

  public:

   AdaptiveFreeList();

   AdaptiveFreeList(Chunk* fc);

   using FreeList<Chunk>::assert_proper_lock_protection;

 #ifdef ASSERT

   using FreeList<Chunk>::protecting_lock;

 #endif

   using FreeList<Chunk>::count;

   using FreeList<Chunk>::size;

   using FreeList<Chunk>::verify_chunk_in_free_list;

   using FreeList<Chunk>::getFirstNChunksFromList;

   using FreeList<Chunk>::print_on;

   void return_chunk_at_head(Chunk* fc, bool record_return);

   void return_chunk_at_head(Chunk* fc);

   void return_chunk_at_tail(Chunk* fc, bool record_return);

   void return_chunk_at_tail(Chunk* fc);

   using FreeList<Chunk>::return_chunk_at_tail;

   using FreeList<Chunk>::remove_chunk;

   using FreeList<Chunk>::prepend;

   using FreeList<Chunk>::print_labels_on;

   using FreeList<Chunk>::get_chunk_at_head;

   // Initialize.

   void initialize();

   // Reset the head, tail, hint, and count of a free list.

   void reset(size_t hint);

   void assert_proper_lock_protection_work() const PRODUCT_RETURN;

   void print_on(outputStream* st, const char* c = NULL) const;

   size_t hint() const {

     return _hint;

   }

   void set_hint(size_t v) {

     assert_proper_lock_protection();

     assert(v == 0 || size() < v, "Bad hint");

     _hint = v;

   }

   size_t get_better_size();

   // Accessors for statistics

   void init_statistics(bool split_birth = false);

   AllocationStats* allocation_stats() {

     assert_proper_lock_protection();

     return &_allocation_stats;

   }

   ssize_t desired() const {

     return _allocation_stats.desired();

   }

   void set_desired(ssize_t v) {

     assert_proper_lock_protection();

     _allocation_stats.set_desired(v);

   }

   void compute_desired(float inter_sweep_current,

                        float inter_sweep_estimate,

                        float intra_sweep_estimate) {

     assert_proper_lock_protection();

     _allocation_stats.compute_desired(count(),

                                       inter_sweep_current,

                                       inter_sweep_estimate,

                                       intra_sweep_estimate);

   }

   ssize_t coal_desired() const {

     return _allocation_stats.coal_desired();

   }

   void set_coal_desired(ssize_t v) {

     assert_proper_lock_protection();

     _allocation_stats.set_coal_desired(v);

   }

   ssize_t surplus() const {

     return _allocation_stats.surplus();

   }

   void set_surplus(ssize_t v) {

     assert_proper_lock_protection();

     _allocation_stats.set_surplus(v);

   }

   void increment_surplus() {

     assert_proper_lock_protection();

     _allocation_stats.increment_surplus();

   }

   void decrement_surplus() {

     assert_proper_lock_protection();

     _allocation_stats.decrement_surplus();

   }

   ssize_t bfr_surp() const {

     return _allocation_stats.bfr_surp();

   }

   void set_bfr_surp(ssize_t v) {

     assert_proper_lock_protection();

     _allocation_stats.set_bfr_surp(v);

   }

   ssize_t prev_sweep() const {

     return _allocation_stats.prev_sweep();

   }

   void set_prev_sweep(ssize_t v) {

     assert_proper_lock_protection();

     _allocation_stats.set_prev_sweep(v);

   }

   ssize_t before_sweep() const {

     return _allocation_stats.before_sweep();

   }

   void set_before_sweep(ssize_t v) {

     assert_proper_lock_protection();

     _allocation_stats.set_before_sweep(v);

   }

   ssize_t coal_births() const {

     return _allocation_stats.coal_births();

   }

   void set_coal_births(ssize_t v) {

     assert_proper_lock_protection();

     _allocation_stats.set_coal_births(v);

   }

   void increment_coal_births() {

     assert_proper_lock_protection();

     _allocation_stats.increment_coal_births();

   }

   ssize_t coal_deaths() const {

     return _allocation_stats.coal_deaths();

   }

   void set_coal_deaths(ssize_t v) {

     assert_proper_lock_protection();

     _allocation_stats.set_coal_deaths(v);

   }

   void increment_coal_deaths() {

     assert_proper_lock_protection();

     _allocation_stats.increment_coal_deaths();

   }

   ssize_t split_births() const {

     return _allocation_stats.split_births();

   }

   void set_split_births(ssize_t v) {

     assert_proper_lock_protection();

     _allocation_stats.set_split_births(v);

   }

   void increment_split_births() {

     assert_proper_lock_protection();

     _allocation_stats.increment_split_births();

   }

   ssize_t split_deaths() const {

     return _allocation_stats.split_deaths();

   }

   void set_split_deaths(ssize_t v) {

     assert_proper_lock_protection();

     _allocation_stats.set_split_deaths(v);

   }

   void increment_split_deaths() {

     assert_proper_lock_protection();

     _allocation_stats.increment_split_deaths();

   }

 #ifndef PRODUCT

   // For debugging.  The "_returned_bytes" in all the lists are summed

   // and compared with the total number of bytes swept during a

   // collection.

   size_t returned_bytes() const { return _allocation_stats.returned_bytes(); }

   void set_returned_bytes(size_t v) { _allocation_stats.set_returned_bytes(v); }

   void increment_returned_bytes_by(size_t v) {

     _allocation_stats.set_returned_bytes(_allocation_stats.returned_bytes() + v);

   }

   // Stats verification

   void verify_stats() const;

 #endif  // NOT PRODUCT

 };

 #endif // SHARE_VM_MEMORY_ADAPTIVEFREELIST_HPP