/* * Copyright (c) 2018, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. * */ #ifndef SHARE_GC_SHARED_OOPSTORAGE_HPP #define SHARE_GC_SHARED_OOPSTORAGE_HPP #include "memory/allocation.hpp" #include "oops/oop.hpp" #include "utilities/globalDefinitions.hpp" #include "utilities/macros.hpp" #include "utilities/singleWriterSynchronizer.hpp" class Mutex; class outputStream; // OopStorage supports management of off-heap references to objects allocated // in the Java heap. An OopStorage object provides a set of Java object // references (oop values), which clients refer to via oop* handles to the // associated OopStorage entries. Clients allocate entries to create a // (possibly weak) reference to a Java object, use that reference, and release // the reference when no longer needed. // // The garbage collector must know about all OopStorage objects and their // reference strength. OopStorage provides the garbage collector with support // for iteration over all the allocated entries. // // There are several categories of interaction with an OopStorage object. // // (1) allocation and release of entries, by the mutator or the VM. // (2) iteration by the garbage collector, possibly concurrent with mutator. // (3) iteration by other, non-GC, tools (only at safepoints). // (4) cleanup of unused internal storage, possibly concurrent with mutator. // // A goal of OopStorage is to make these interactions thread-safe, while // minimizing potential lock contention issues within and between these // categories. In particular, support for concurrent iteration by the garbage // collector, under certain restrictions, is required. Further, it must not // block nor be blocked by other operations for long periods. // // Internally, OopStorage is a set of Block objects, from which entries are // allocated and released. A block contains an oop[] and a bitmask indicating // which entries are in use (have been allocated and not yet released). New // blocks are constructed and added to the storage object when an entry // allocation request is made and there are no blocks with unused entries. // Blocks may be removed and deleted when empty. // // There are two important (and somewhat intertwined) protocols governing // concurrent access to a storage object. These are the Concurrent Iteration // Protocol and the Allocation Protocol. See the ParState class for a // discussion of concurrent iteration and the management of thread // interactions for this protocol. Similarly, see the allocate() function for // a discussion of allocation. class OopStorage : public CHeapObj { public: OopStorage(const char* name, Mutex* allocation_mutex, Mutex* active_mutex); ~OopStorage(); // These count and usage accessors are racy unless at a safepoint. // The number of allocated and not yet released entries. size_t allocation_count() const; // The number of blocks of entries. Useful for sizing parallel iteration. size_t block_count() const; // Total number of blocks * memory allocation per block, plus // bookkeeping overhead, including this storage object. size_t total_memory_usage() const; enum EntryStatus { INVALID_ENTRY, UNALLOCATED_ENTRY, ALLOCATED_ENTRY }; // Locks _allocation_mutex. // precondition: ptr != NULL. EntryStatus allocation_status(const oop* ptr) const; // Allocates and returns a new entry. Returns NULL if memory allocation // failed. Locks _allocation_mutex. // postcondition: *result == NULL. oop* allocate(); // Deallocates ptr. No locking. // precondition: ptr is a valid allocated entry. // precondition: *ptr == NULL. void release(const oop* ptr); // Releases all the ptrs. Possibly faster than individual calls to // release(oop*). Best if ptrs is sorted by address. No locking. // precondition: All elements of ptrs are valid allocated entries. // precondition: *ptrs[i] == NULL, for i in [0,size). void release(const oop* const* ptrs, size_t size); // Applies f to each allocated entry's location. f must be a function or // function object. Assume p is either a const oop* or an oop*, depending // on whether the associated storage is const or non-const, respectively. // Then f(p) must be a valid expression. The result of invoking f(p) must // be implicitly convertible to bool. Iteration terminates and returns // false if any invocation of f returns false. Otherwise, the result of // iteration is true. // precondition: at safepoint. template inline bool iterate_safepoint(F f); template inline bool iterate_safepoint(F f) const; // oops_do and weak_oops_do are wrappers around iterate_safepoint, providing // an adaptation layer allowing the use of existing is-alive closures and // OopClosures. Assume p is either const oop* or oop*, depending on whether // the associated storage is const or non-const, respectively. Then // // - closure->do_oop(p) must be a valid expression whose value is ignored. // // - is_alive->do_object_b(*p) must be a valid expression whose value is // convertible to bool. // // For weak_oops_do, if *p == NULL then neither is_alive nor closure will be // invoked for p. If is_alive->do_object_b(*p) is false, then closure will // not be invoked on p, and *p will be set to NULL. template inline void oops_do(Closure* closure); template inline void oops_do(Closure* closure) const; template inline void weak_oops_do(Closure* closure); template inline void weak_oops_do(IsAliveClosure* is_alive, Closure* closure); // Parallel iteration is for the exclusive use of the GC. // Other clients must use serial iteration. template class ParState; // Block cleanup functions are for the exclusive use of the GC. // Both stop deleting if there is an in-progress concurrent iteration. // Concurrent deletion locks both the _allocation_mutex and the _active_mutex. void delete_empty_blocks_safepoint(); void delete_empty_blocks_concurrent(); // Debugging and logging support. const char* name() const; void print_on(outputStream* st) const PRODUCT_RETURN; // Provides access to storage internals, for unit testing. // Declare, but not define, the public class OopStorage::TestAccess. // That class is defined as part of the unit-test. It "exports" the needed // private types by providing public typedefs for them. class TestAccess; // xlC on AIX can't compile test_oopStorage.cpp with following private // classes. C++03 introduced access for nested classes with DR45, but xlC // version 12 rejects it. NOT_AIX( private: ) class Block; // Fixed-size array of oops, plus bookkeeping. class ActiveArray; // Array of Blocks, plus bookkeeping. class AllocationListEntry; // Provides AllocationList links in a Block. // Doubly-linked list of Blocks. class AllocationList { const Block* _head; const Block* _tail; // Noncopyable. AllocationList(const AllocationList&); AllocationList& operator=(const AllocationList&); public: AllocationList(); ~AllocationList(); Block* head(); Block* tail(); const Block* chead() const; const Block* ctail() const; Block* prev(Block& block); Block* next(Block& block); const Block* prev(const Block& block) const; const Block* next(const Block& block) const; void push_front(const Block& block); void push_back(const Block& block); void unlink(const Block& block); }; private: const char* _name; ActiveArray* _active_array; AllocationList _allocation_list; Block* volatile _deferred_updates; Mutex* _allocation_mutex; Mutex* _active_mutex; // Volatile for racy unlocked accesses. volatile size_t _allocation_count; // Protection for _active_array. mutable SingleWriterSynchronizer _protect_active; // mutable because this gets set even for const iteration. mutable int _concurrent_iteration_count; Block* find_block_or_null(const oop* ptr) const; void delete_empty_block(const Block& block); bool reduce_deferred_updates(); // Managing _active_array. bool expand_active_array(); void replace_active_array(ActiveArray* new_array); ActiveArray* obtain_active_array() const; void relinquish_block_array(ActiveArray* array) const; class WithActiveArray; // RAII helper for active array access. template static bool iterate_impl(F f, Storage* storage); // Implementation support for parallel iteration class BasicParState; // Wrapper for OopClosure-style function, so it can be used with // iterate. Assume p is of type oop*. Then cl->do_oop(p) must be a // valid expression whose value may be ignored. template class OopFn; template static OopFn oop_fn(Closure* cl); // Wrapper for BoolObjectClosure + iteration handler pair, so they // can be used with iterate. template class IfAliveFn; template static IfAliveFn if_alive_fn(IsAlive* is_alive, F f); // Wrapper for iteration handler, automatically skipping NULL entries. template class SkipNullFn; template static SkipNullFn skip_null_fn(F f); }; #endif // include guard