8202021: Improve variable naming in ReferenceProcesso
Reviewed-by: sangheki, sjohanss
/*
* Copyright (c) 2001, 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
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*/
#include "precompiled.hpp"
#include "gc/g1/g1BlockOffsetTable.inline.hpp"
#include "gc/g1/g1CollectedHeap.inline.hpp"
#include "gc/g1/g1ConcurrentRefine.hpp"
#include "gc/g1/heapRegionManager.inline.hpp"
#include "gc/g1/heapRegionRemSet.hpp"
#include "gc/shared/space.inline.hpp"
#include "memory/allocation.hpp"
#include "memory/padded.inline.hpp"
#include "oops/oop.inline.hpp"
#include "runtime/atomic.hpp"
#include "utilities/bitMap.inline.hpp"
#include "utilities/debug.hpp"
#include "utilities/formatBuffer.hpp"
#include "utilities/globalDefinitions.hpp"
#include "utilities/growableArray.hpp"
const char* HeapRegionRemSet::_state_strings[] = {"Untracked", "Updating", "Complete"};
const char* HeapRegionRemSet::_short_state_strings[] = {"UNTRA", "UPDAT", "CMPLT"};
class PerRegionTable: public CHeapObj<mtGC> {
friend class OtherRegionsTable;
friend class HeapRegionRemSetIterator;
HeapRegion* _hr;
CHeapBitMap _bm;
jint _occupied;
// next pointer for free/allocated 'all' list
PerRegionTable* _next;
// prev pointer for the allocated 'all' list
PerRegionTable* _prev;
// next pointer in collision list
PerRegionTable * _collision_list_next;
// Global free list of PRTs
static PerRegionTable* volatile _free_list;
protected:
// We need access in order to union things into the base table.
BitMap* bm() { return &_bm; }
PerRegionTable(HeapRegion* hr) :
_hr(hr),
_occupied(0),
_bm(HeapRegion::CardsPerRegion, mtGC),
_collision_list_next(NULL), _next(NULL), _prev(NULL)
{}
void add_card_work(CardIdx_t from_card, bool par) {
if (!_bm.at(from_card)) {
if (par) {
if (_bm.par_at_put(from_card, 1)) {
Atomic::inc(&_occupied);
}
} else {
_bm.at_put(from_card, 1);
_occupied++;
}
}
}
void add_reference_work(OopOrNarrowOopStar from, bool par) {
// Must make this robust in case "from" is not in "_hr", because of
// concurrency.
HeapRegion* loc_hr = hr();
// If the test below fails, then this table was reused concurrently
// with this operation. This is OK, since the old table was coarsened,
// and adding a bit to the new table is never incorrect.
if (loc_hr->is_in_reserved(from)) {
CardIdx_t from_card = OtherRegionsTable::card_within_region(from, loc_hr);
add_card_work(from_card, par);
}
}
public:
HeapRegion* hr() const { return OrderAccess::load_acquire(&_hr); }
jint occupied() const {
// Overkill, but if we ever need it...
// guarantee(_occupied == _bm.count_one_bits(), "Check");
return _occupied;
}
void init(HeapRegion* hr, bool clear_links_to_all_list) {
if (clear_links_to_all_list) {
set_next(NULL);
set_prev(NULL);
}
_collision_list_next = NULL;
_occupied = 0;
_bm.clear();
// Make sure that the bitmap clearing above has been finished before publishing
// this PRT to concurrent threads.
OrderAccess::release_store(&_hr, hr);
}
void add_reference(OopOrNarrowOopStar from) {
add_reference_work(from, /*parallel*/ true);
}
void seq_add_reference(OopOrNarrowOopStar from) {
add_reference_work(from, /*parallel*/ false);
}
void add_card(CardIdx_t from_card_index) {
add_card_work(from_card_index, /*parallel*/ true);
}
void seq_add_card(CardIdx_t from_card_index) {
add_card_work(from_card_index, /*parallel*/ false);
}
// (Destructively) union the bitmap of the current table into the given
// bitmap (which is assumed to be of the same size.)
void union_bitmap_into(BitMap* bm) {
bm->set_union(_bm);
}
// Mem size in bytes.
size_t mem_size() const {
return sizeof(PerRegionTable) + _bm.size_in_words() * HeapWordSize;
}
// Requires "from" to be in "hr()".
bool contains_reference(OopOrNarrowOopStar from) const {
assert(hr()->is_in_reserved(from), "Precondition.");
size_t card_ind = pointer_delta(from, hr()->bottom(),
G1CardTable::card_size);
return _bm.at(card_ind);
}
// Bulk-free the PRTs from prt to last, assumes that they are
// linked together using their _next field.
static void bulk_free(PerRegionTable* prt, PerRegionTable* last) {
while (true) {
PerRegionTable* fl = _free_list;
last->set_next(fl);
PerRegionTable* res = Atomic::cmpxchg(prt, &_free_list, fl);
if (res == fl) {
return;
}
}
ShouldNotReachHere();
}
static void free(PerRegionTable* prt) {
bulk_free(prt, prt);
}
// Returns an initialized PerRegionTable instance.
static PerRegionTable* alloc(HeapRegion* hr) {
PerRegionTable* fl = _free_list;
while (fl != NULL) {
PerRegionTable* nxt = fl->next();
PerRegionTable* res = Atomic::cmpxchg(nxt, &_free_list, fl);
if (res == fl) {
fl->init(hr, true);
return fl;
} else {
fl = _free_list;
}
}
assert(fl == NULL, "Loop condition.");
return new PerRegionTable(hr);
}
PerRegionTable* next() const { return _next; }
void set_next(PerRegionTable* next) { _next = next; }
PerRegionTable* prev() const { return _prev; }
void set_prev(PerRegionTable* prev) { _prev = prev; }
// Accessor and Modification routines for the pointer for the
// singly linked collision list that links the PRTs within the
// OtherRegionsTable::_fine_grain_regions hash table.
//
// It might be useful to also make the collision list doubly linked
// to avoid iteration over the collisions list during scrubbing/deletion.
// OTOH there might not be many collisions.
PerRegionTable* collision_list_next() const {
return _collision_list_next;
}
void set_collision_list_next(PerRegionTable* next) {
_collision_list_next = next;
}
PerRegionTable** collision_list_next_addr() {
return &_collision_list_next;
}
static size_t fl_mem_size() {
PerRegionTable* cur = _free_list;
size_t res = 0;
while (cur != NULL) {
res += cur->mem_size();
cur = cur->next();
}
return res;
}
static void test_fl_mem_size();
};
PerRegionTable* volatile PerRegionTable::_free_list = NULL;
size_t OtherRegionsTable::_max_fine_entries = 0;
size_t OtherRegionsTable::_mod_max_fine_entries_mask = 0;
size_t OtherRegionsTable::_fine_eviction_stride = 0;
size_t OtherRegionsTable::_fine_eviction_sample_size = 0;
OtherRegionsTable::OtherRegionsTable(HeapRegion* hr, Mutex* m) :
_g1h(G1CollectedHeap::heap()),
_hr(hr), _m(m),
_coarse_map(G1CollectedHeap::heap()->max_regions(), mtGC),
_fine_grain_regions(NULL),
_first_all_fine_prts(NULL), _last_all_fine_prts(NULL),
_n_fine_entries(0), _n_coarse_entries(0),
_fine_eviction_start(0),
_sparse_table(hr)
{
typedef PerRegionTable* PerRegionTablePtr;
if (_max_fine_entries == 0) {
assert(_mod_max_fine_entries_mask == 0, "Both or none.");
size_t max_entries_log = (size_t)log2_long((jlong)G1RSetRegionEntries);
_max_fine_entries = (size_t)1 << max_entries_log;
_mod_max_fine_entries_mask = _max_fine_entries - 1;
assert(_fine_eviction_sample_size == 0
&& _fine_eviction_stride == 0, "All init at same time.");
_fine_eviction_sample_size = MAX2((size_t)4, max_entries_log);
_fine_eviction_stride = _max_fine_entries / _fine_eviction_sample_size;
}
_fine_grain_regions = NEW_C_HEAP_ARRAY3(PerRegionTablePtr, _max_fine_entries,
mtGC, CURRENT_PC, AllocFailStrategy::RETURN_NULL);
if (_fine_grain_regions == NULL) {
vm_exit_out_of_memory(sizeof(void*)*_max_fine_entries, OOM_MALLOC_ERROR,
"Failed to allocate _fine_grain_entries.");
}
for (size_t i = 0; i < _max_fine_entries; i++) {
_fine_grain_regions[i] = NULL;
}
}
void OtherRegionsTable::link_to_all(PerRegionTable* prt) {
// We always append to the beginning of the list for convenience;
// the order of entries in this list does not matter.
if (_first_all_fine_prts != NULL) {
assert(_first_all_fine_prts->prev() == NULL, "invariant");
_first_all_fine_prts->set_prev(prt);
prt->set_next(_first_all_fine_prts);
} else {
// this is the first element we insert. Adjust the "last" pointer
_last_all_fine_prts = prt;
assert(prt->next() == NULL, "just checking");
}
// the new element is always the first element without a predecessor
prt->set_prev(NULL);
_first_all_fine_prts = prt;
assert(prt->prev() == NULL, "just checking");
assert(_first_all_fine_prts == prt, "just checking");
assert((_first_all_fine_prts == NULL && _last_all_fine_prts == NULL) ||
(_first_all_fine_prts != NULL && _last_all_fine_prts != NULL),
"just checking");
assert(_last_all_fine_prts == NULL || _last_all_fine_prts->next() == NULL,
"just checking");
assert(_first_all_fine_prts == NULL || _first_all_fine_prts->prev() == NULL,
"just checking");
}
void OtherRegionsTable::unlink_from_all(PerRegionTable* prt) {
if (prt->prev() != NULL) {
assert(_first_all_fine_prts != prt, "just checking");
prt->prev()->set_next(prt->next());
// removing the last element in the list?
if (_last_all_fine_prts == prt) {
_last_all_fine_prts = prt->prev();
}
} else {
assert(_first_all_fine_prts == prt, "just checking");
_first_all_fine_prts = prt->next();
// list is empty now?
if (_first_all_fine_prts == NULL) {
_last_all_fine_prts = NULL;
}
}
if (prt->next() != NULL) {
prt->next()->set_prev(prt->prev());
}
prt->set_next(NULL);
prt->set_prev(NULL);
assert((_first_all_fine_prts == NULL && _last_all_fine_prts == NULL) ||
(_first_all_fine_prts != NULL && _last_all_fine_prts != NULL),
"just checking");
assert(_last_all_fine_prts == NULL || _last_all_fine_prts->next() == NULL,
"just checking");
assert(_first_all_fine_prts == NULL || _first_all_fine_prts->prev() == NULL,
"just checking");
}
CardIdx_t OtherRegionsTable::card_within_region(OopOrNarrowOopStar within_region, HeapRegion* hr) {
assert(hr->is_in_reserved(within_region),
"HeapWord " PTR_FORMAT " is outside of region %u [" PTR_FORMAT ", " PTR_FORMAT ")",
p2i(within_region), hr->hrm_index(), p2i(hr->bottom()), p2i(hr->end()));
CardIdx_t result = (CardIdx_t)(pointer_delta((HeapWord*)within_region, hr->bottom()) >> (CardTable::card_shift - LogHeapWordSize));
return result;
}
void OtherRegionsTable::add_reference(OopOrNarrowOopStar from, uint tid) {
uint cur_hrm_ind = _hr->hrm_index();
uintptr_t from_card = uintptr_t(from) >> CardTable::card_shift;
if (G1FromCardCache::contains_or_replace(tid, cur_hrm_ind, from_card)) {
assert(contains_reference(from), "We just found " PTR_FORMAT " in the FromCardCache", p2i(from));
return;
}
// Note that this may be a continued H region.
HeapRegion* from_hr = _g1h->heap_region_containing(from);
RegionIdx_t from_hrm_ind = (RegionIdx_t) from_hr->hrm_index();
// If the region is already coarsened, return.
if (_coarse_map.at(from_hrm_ind)) {
assert(contains_reference(from), "We just found " PTR_FORMAT " in the Coarse table", p2i(from));
return;
}
// Otherwise find a per-region table to add it to.
size_t ind = from_hrm_ind & _mod_max_fine_entries_mask;
PerRegionTable* prt = find_region_table(ind, from_hr);
if (prt == NULL) {
MutexLockerEx x(_m, Mutex::_no_safepoint_check_flag);
// Confirm that it's really not there...
prt = find_region_table(ind, from_hr);
if (prt == NULL) {
CardIdx_t card_index = card_within_region(from, from_hr);
if (G1HRRSUseSparseTable &&
_sparse_table.add_card(from_hrm_ind, card_index)) {
assert(contains_reference_locked(from), "We just added " PTR_FORMAT " to the Sparse table", p2i(from));
return;
}
if (_n_fine_entries == _max_fine_entries) {
prt = delete_region_table();
// There is no need to clear the links to the 'all' list here:
// prt will be reused immediately, i.e. remain in the 'all' list.
prt->init(from_hr, false /* clear_links_to_all_list */);
} else {
prt = PerRegionTable::alloc(from_hr);
link_to_all(prt);
}
PerRegionTable* first_prt = _fine_grain_regions[ind];
prt->set_collision_list_next(first_prt);
// The assignment into _fine_grain_regions allows the prt to
// start being used concurrently. In addition to
// collision_list_next which must be visible (else concurrent
// parsing of the list, if any, may fail to see other entries),
// the content of the prt must be visible (else for instance
// some mark bits may not yet seem cleared or a 'later' update
// performed by a concurrent thread could be undone when the
// zeroing becomes visible). This requires store ordering.
OrderAccess::release_store(&_fine_grain_regions[ind], prt);
_n_fine_entries++;
if (G1HRRSUseSparseTable) {
// Transfer from sparse to fine-grain.
SparsePRTEntry *sprt_entry = _sparse_table.get_entry(from_hrm_ind);
assert(sprt_entry != NULL, "There should have been an entry");
for (int i = 0; i < sprt_entry->num_valid_cards(); i++) {
CardIdx_t c = sprt_entry->card(i);
prt->add_card(c);
}
// Now we can delete the sparse entry.
bool res = _sparse_table.delete_entry(from_hrm_ind);
assert(res, "It should have been there.");
}
}
assert(prt != NULL && prt->hr() == from_hr, "consequence");
}
// Note that we can't assert "prt->hr() == from_hr", because of the
// possibility of concurrent reuse. But see head comment of
// OtherRegionsTable for why this is OK.
assert(prt != NULL, "Inv");
prt->add_reference(from);
assert(contains_reference(from), "We just added " PTR_FORMAT " to the PRT (%d)", p2i(from), prt->contains_reference(from));
}
PerRegionTable*
OtherRegionsTable::find_region_table(size_t ind, HeapRegion* hr) const {
assert(ind < _max_fine_entries, "Preconditions.");
PerRegionTable* prt = _fine_grain_regions[ind];
while (prt != NULL && prt->hr() != hr) {
prt = prt->collision_list_next();
}
// Loop postcondition is the method postcondition.
return prt;
}
jint OtherRegionsTable::_n_coarsenings = 0;
PerRegionTable* OtherRegionsTable::delete_region_table() {
assert(_m->owned_by_self(), "Precondition");
assert(_n_fine_entries == _max_fine_entries, "Precondition");
PerRegionTable* max = NULL;
jint max_occ = 0;
PerRegionTable** max_prev = NULL;
size_t max_ind;
size_t i = _fine_eviction_start;
for (size_t k = 0; k < _fine_eviction_sample_size; k++) {
size_t ii = i;
// Make sure we get a non-NULL sample.
while (_fine_grain_regions[ii] == NULL) {
ii++;
if (ii == _max_fine_entries) ii = 0;
guarantee(ii != i, "We must find one.");
}
PerRegionTable** prev = &_fine_grain_regions[ii];
PerRegionTable* cur = *prev;
while (cur != NULL) {
jint cur_occ = cur->occupied();
if (max == NULL || cur_occ > max_occ) {
max = cur;
max_prev = prev;
max_ind = i;
max_occ = cur_occ;
}
prev = cur->collision_list_next_addr();
cur = cur->collision_list_next();
}
i = i + _fine_eviction_stride;
if (i >= _n_fine_entries) i = i - _n_fine_entries;
}
_fine_eviction_start++;
if (_fine_eviction_start >= _n_fine_entries) {
_fine_eviction_start -= _n_fine_entries;
}
guarantee(max != NULL, "Since _n_fine_entries > 0");
guarantee(max_prev != NULL, "Since max != NULL.");
// Set the corresponding coarse bit.
size_t max_hrm_index = (size_t) max->hr()->hrm_index();
if (!_coarse_map.at(max_hrm_index)) {
_coarse_map.at_put(max_hrm_index, true);
_n_coarse_entries++;
}
// Unsplice.
*max_prev = max->collision_list_next();
Atomic::inc(&_n_coarsenings);
_n_fine_entries--;
return max;
}
bool OtherRegionsTable::occupancy_less_or_equal_than(size_t limit) const {
if (limit <= (size_t)G1RSetSparseRegionEntries) {
return occ_coarse() == 0 && _first_all_fine_prts == NULL && occ_sparse() <= limit;
} else {
// Current uses of this method may only use values less than G1RSetSparseRegionEntries
// for the limit. The solution, comparing against occupied() would be too slow
// at this time.
Unimplemented();
return false;
}
}
bool OtherRegionsTable::is_empty() const {
return occ_sparse() == 0 && occ_coarse() == 0 && _first_all_fine_prts == NULL;
}
size_t OtherRegionsTable::occupied() const {
size_t sum = occ_fine();
sum += occ_sparse();
sum += occ_coarse();
return sum;
}
size_t OtherRegionsTable::occ_fine() const {
size_t sum = 0;
size_t num = 0;
PerRegionTable * cur = _first_all_fine_prts;
while (cur != NULL) {
sum += cur->occupied();
cur = cur->next();
num++;
}
guarantee(num == _n_fine_entries, "just checking");
return sum;
}
size_t OtherRegionsTable::occ_coarse() const {
return (_n_coarse_entries * HeapRegion::CardsPerRegion);
}
size_t OtherRegionsTable::occ_sparse() const {
return _sparse_table.occupied();
}
size_t OtherRegionsTable::mem_size() const {
size_t sum = 0;
// all PRTs are of the same size so it is sufficient to query only one of them.
if (_first_all_fine_prts != NULL) {
assert(_last_all_fine_prts != NULL &&
_first_all_fine_prts->mem_size() == _last_all_fine_prts->mem_size(), "check that mem_size() is constant");
sum += _first_all_fine_prts->mem_size() * _n_fine_entries;
}
sum += (sizeof(PerRegionTable*) * _max_fine_entries);
sum += (_coarse_map.size_in_words() * HeapWordSize);
sum += (_sparse_table.mem_size());
sum += sizeof(OtherRegionsTable) - sizeof(_sparse_table); // Avoid double counting above.
return sum;
}
size_t OtherRegionsTable::static_mem_size() {
return G1FromCardCache::static_mem_size();
}
size_t OtherRegionsTable::fl_mem_size() {
return PerRegionTable::fl_mem_size();
}
void OtherRegionsTable::clear_fcc() {
G1FromCardCache::clear(_hr->hrm_index());
}
void OtherRegionsTable::clear() {
// if there are no entries, skip this step
if (_first_all_fine_prts != NULL) {
guarantee(_first_all_fine_prts != NULL && _last_all_fine_prts != NULL, "just checking");
PerRegionTable::bulk_free(_first_all_fine_prts, _last_all_fine_prts);
memset(_fine_grain_regions, 0, _max_fine_entries * sizeof(_fine_grain_regions[0]));
} else {
guarantee(_first_all_fine_prts == NULL && _last_all_fine_prts == NULL, "just checking");
}
_first_all_fine_prts = _last_all_fine_prts = NULL;
_sparse_table.clear();
if (_n_coarse_entries > 0) {
_coarse_map.clear();
}
_n_fine_entries = 0;
_n_coarse_entries = 0;
clear_fcc();
}
bool OtherRegionsTable::contains_reference(OopOrNarrowOopStar from) const {
// Cast away const in this case.
MutexLockerEx x((Mutex*)_m, Mutex::_no_safepoint_check_flag);
return contains_reference_locked(from);
}
bool OtherRegionsTable::contains_reference_locked(OopOrNarrowOopStar from) const {
HeapRegion* hr = _g1h->heap_region_containing(from);
RegionIdx_t hr_ind = (RegionIdx_t) hr->hrm_index();
// Is this region in the coarse map?
if (_coarse_map.at(hr_ind)) return true;
PerRegionTable* prt = find_region_table(hr_ind & _mod_max_fine_entries_mask,
hr);
if (prt != NULL) {
return prt->contains_reference(from);
} else {
CardIdx_t card_index = card_within_region(from, hr);
return _sparse_table.contains_card(hr_ind, card_index);
}
}
void
OtherRegionsTable::do_cleanup_work(HRRSCleanupTask* hrrs_cleanup_task) {
_sparse_table.do_cleanup_work(hrrs_cleanup_task);
}
HeapRegionRemSet::HeapRegionRemSet(G1BlockOffsetTable* bot,
HeapRegion* hr)
: _bot(bot),
_m(Mutex::leaf, FormatBuffer<128>("HeapRegionRemSet lock #%u", hr->hrm_index()), true, Monitor::_safepoint_check_never),
_code_roots(),
_state(Untracked),
_other_regions(hr, &_m) {
}
void HeapRegionRemSet::setup_remset_size() {
// Setup sparse and fine-grain tables sizes.
// table_size = base * (log(region_size / 1M) + 1)
const int LOG_M = 20;
int region_size_log_mb = MAX2(HeapRegion::LogOfHRGrainBytes - LOG_M, 0);
if (FLAG_IS_DEFAULT(G1RSetSparseRegionEntries)) {
G1RSetSparseRegionEntries = G1RSetSparseRegionEntriesBase * (region_size_log_mb + 1);
}
if (FLAG_IS_DEFAULT(G1RSetRegionEntries)) {
G1RSetRegionEntries = G1RSetRegionEntriesBase * (region_size_log_mb + 1);
}
guarantee(G1RSetSparseRegionEntries > 0 && G1RSetRegionEntries > 0 , "Sanity");
}
void HeapRegionRemSet::cleanup() {
SparsePRT::cleanup_all();
}
void HeapRegionRemSet::clear(bool only_cardset) {
MutexLockerEx x(&_m, Mutex::_no_safepoint_check_flag);
clear_locked(only_cardset);
}
void HeapRegionRemSet::clear_locked(bool only_cardset) {
if (!only_cardset) {
_code_roots.clear();
}
_other_regions.clear();
set_state_empty();
assert(occupied_locked() == 0, "Should be clear.");
}
// Code roots support
//
// The code root set is protected by two separate locking schemes
// When at safepoint the per-hrrs lock must be held during modifications
// except when doing a full gc.
// When not at safepoint the CodeCache_lock must be held during modifications.
// When concurrent readers access the contains() function
// (during the evacuation phase) no removals are allowed.
void HeapRegionRemSet::add_strong_code_root(nmethod* nm) {
assert(nm != NULL, "sanity");
assert((!CodeCache_lock->owned_by_self() || SafepointSynchronize::is_at_safepoint()),
"should call add_strong_code_root_locked instead. CodeCache_lock->owned_by_self(): %s, is_at_safepoint(): %s",
BOOL_TO_STR(CodeCache_lock->owned_by_self()), BOOL_TO_STR(SafepointSynchronize::is_at_safepoint()));
// Optimistic unlocked contains-check
if (!_code_roots.contains(nm)) {
MutexLockerEx ml(&_m, Mutex::_no_safepoint_check_flag);
add_strong_code_root_locked(nm);
}
}
void HeapRegionRemSet::add_strong_code_root_locked(nmethod* nm) {
assert(nm != NULL, "sanity");
assert((CodeCache_lock->owned_by_self() ||
(SafepointSynchronize::is_at_safepoint() &&
(_m.owned_by_self() || Thread::current()->is_VM_thread()))),
"not safely locked. CodeCache_lock->owned_by_self(): %s, is_at_safepoint(): %s, _m.owned_by_self(): %s, Thread::current()->is_VM_thread(): %s",
BOOL_TO_STR(CodeCache_lock->owned_by_self()), BOOL_TO_STR(SafepointSynchronize::is_at_safepoint()),
BOOL_TO_STR(_m.owned_by_self()), BOOL_TO_STR(Thread::current()->is_VM_thread()));
_code_roots.add(nm);
}
void HeapRegionRemSet::remove_strong_code_root(nmethod* nm) {
assert(nm != NULL, "sanity");
assert_locked_or_safepoint(CodeCache_lock);
MutexLockerEx ml(CodeCache_lock->owned_by_self() ? NULL : &_m, Mutex::_no_safepoint_check_flag);
_code_roots.remove(nm);
// Check that there were no duplicates
guarantee(!_code_roots.contains(nm), "duplicate entry found");
}
void HeapRegionRemSet::strong_code_roots_do(CodeBlobClosure* blk) const {
_code_roots.nmethods_do(blk);
}
void HeapRegionRemSet::clean_strong_code_roots(HeapRegion* hr) {
_code_roots.clean(hr);
}
size_t HeapRegionRemSet::strong_code_roots_mem_size() {
return _code_roots.mem_size();
}
HeapRegionRemSetIterator:: HeapRegionRemSetIterator(HeapRegionRemSet* hrrs) :
_hrrs(hrrs),
_g1h(G1CollectedHeap::heap()),
_coarse_map(&hrrs->_other_regions._coarse_map),
_bot(hrrs->_bot),
_is(Sparse),
// Set these values so that we increment to the first region.
_coarse_cur_region_index(-1),
_coarse_cur_region_cur_card(HeapRegion::CardsPerRegion-1),
_cur_card_in_prt(HeapRegion::CardsPerRegion),
_fine_cur_prt(NULL),
_n_yielded_coarse(0),
_n_yielded_fine(0),
_n_yielded_sparse(0),
_sparse_iter(&hrrs->_other_regions._sparse_table) {}
bool HeapRegionRemSetIterator::coarse_has_next(size_t& card_index) {
if (_hrrs->_other_regions._n_coarse_entries == 0) return false;
// Go to the next card.
_coarse_cur_region_cur_card++;
// Was the last the last card in the current region?
if (_coarse_cur_region_cur_card == HeapRegion::CardsPerRegion) {
// Yes: find the next region. This may leave _coarse_cur_region_index
// Set to the last index, in which case there are no more coarse
// regions.
_coarse_cur_region_index =
(int) _coarse_map->get_next_one_offset(_coarse_cur_region_index + 1);
if ((size_t)_coarse_cur_region_index < _coarse_map->size()) {
_coarse_cur_region_cur_card = 0;
HeapWord* r_bot =
_g1h->region_at((uint) _coarse_cur_region_index)->bottom();
_cur_region_card_offset = _bot->index_for(r_bot);
} else {
return false;
}
}
// If we didn't return false above, then we can yield a card.
card_index = _cur_region_card_offset + _coarse_cur_region_cur_card;
return true;
}
bool HeapRegionRemSetIterator::fine_has_next(size_t& card_index) {
if (fine_has_next()) {
_cur_card_in_prt =
_fine_cur_prt->_bm.get_next_one_offset(_cur_card_in_prt + 1);
}
if (_cur_card_in_prt == HeapRegion::CardsPerRegion) {
// _fine_cur_prt may still be NULL in case if there are not PRTs at all for
// the remembered set.
if (_fine_cur_prt == NULL || _fine_cur_prt->next() == NULL) {
return false;
}
PerRegionTable* next_prt = _fine_cur_prt->next();
switch_to_prt(next_prt);
_cur_card_in_prt = _fine_cur_prt->_bm.get_next_one_offset(_cur_card_in_prt + 1);
}
card_index = _cur_region_card_offset + _cur_card_in_prt;
guarantee(_cur_card_in_prt < HeapRegion::CardsPerRegion,
"Card index " SIZE_FORMAT " must be within the region", _cur_card_in_prt);
return true;
}
bool HeapRegionRemSetIterator::fine_has_next() {
return _cur_card_in_prt != HeapRegion::CardsPerRegion;
}
void HeapRegionRemSetIterator::switch_to_prt(PerRegionTable* prt) {
assert(prt != NULL, "Cannot switch to NULL prt");
_fine_cur_prt = prt;
HeapWord* r_bot = _fine_cur_prt->hr()->bottom();
_cur_region_card_offset = _bot->index_for(r_bot);
// The bitmap scan for the PRT always scans from _cur_region_cur_card + 1.
// To avoid special-casing this start case, and not miss the first bitmap
// entry, initialize _cur_region_cur_card with -1 instead of 0.
_cur_card_in_prt = (size_t)-1;
}
bool HeapRegionRemSetIterator::has_next(size_t& card_index) {
switch (_is) {
case Sparse: {
if (_sparse_iter.has_next(card_index)) {
_n_yielded_sparse++;
return true;
}
// Otherwise, deliberate fall-through
_is = Fine;
PerRegionTable* initial_fine_prt = _hrrs->_other_regions._first_all_fine_prts;
if (initial_fine_prt != NULL) {
switch_to_prt(_hrrs->_other_regions._first_all_fine_prts);
}
}
case Fine:
if (fine_has_next(card_index)) {
_n_yielded_fine++;
return true;
}
// Otherwise, deliberate fall-through
_is = Coarse;
case Coarse:
if (coarse_has_next(card_index)) {
_n_yielded_coarse++;
return true;
}
// Otherwise...
break;
}
return false;
}
void HeapRegionRemSet::reset_for_cleanup_tasks() {
SparsePRT::reset_for_cleanup_tasks();
}
void HeapRegionRemSet::do_cleanup_work(HRRSCleanupTask* hrrs_cleanup_task) {
_other_regions.do_cleanup_work(hrrs_cleanup_task);
}
void HeapRegionRemSet::finish_cleanup_task(HRRSCleanupTask* hrrs_cleanup_task) {
SparsePRT::finish_cleanup_task(hrrs_cleanup_task);
}
#ifndef PRODUCT
void HeapRegionRemSet::test() {
os::sleep(Thread::current(), (jlong)5000, false);
G1CollectedHeap* g1h = G1CollectedHeap::heap();
// Run with "-XX:G1LogRSetRegionEntries=2", so that 1 and 5 end up in same
// hash bucket.
HeapRegion* hr0 = g1h->region_at(0);
HeapRegion* hr1 = g1h->region_at(1);
HeapRegion* hr2 = g1h->region_at(5);
HeapRegion* hr3 = g1h->region_at(6);
HeapRegion* hr4 = g1h->region_at(7);
HeapRegion* hr5 = g1h->region_at(8);
HeapWord* hr1_start = hr1->bottom();
HeapWord* hr1_mid = hr1_start + HeapRegion::GrainWords/2;
HeapWord* hr1_last = hr1->end() - 1;
HeapWord* hr2_start = hr2->bottom();
HeapWord* hr2_mid = hr2_start + HeapRegion::GrainWords/2;
HeapWord* hr2_last = hr2->end() - 1;
HeapWord* hr3_start = hr3->bottom();
HeapWord* hr3_mid = hr3_start + HeapRegion::GrainWords/2;
HeapWord* hr3_last = hr3->end() - 1;
HeapRegionRemSet* hrrs = hr0->rem_set();
// Make three references from region 0x101...
hrrs->add_reference((OopOrNarrowOopStar)hr1_start);
hrrs->add_reference((OopOrNarrowOopStar)hr1_mid);
hrrs->add_reference((OopOrNarrowOopStar)hr1_last);
hrrs->add_reference((OopOrNarrowOopStar)hr2_start);
hrrs->add_reference((OopOrNarrowOopStar)hr2_mid);
hrrs->add_reference((OopOrNarrowOopStar)hr2_last);
hrrs->add_reference((OopOrNarrowOopStar)hr3_start);
hrrs->add_reference((OopOrNarrowOopStar)hr3_mid);
hrrs->add_reference((OopOrNarrowOopStar)hr3_last);
// Now cause a coarsening.
hrrs->add_reference((OopOrNarrowOopStar)hr4->bottom());
hrrs->add_reference((OopOrNarrowOopStar)hr5->bottom());
// Now, does iteration yield these three?
HeapRegionRemSetIterator iter(hrrs);
size_t sum = 0;
size_t card_index;
while (iter.has_next(card_index)) {
HeapWord* card_start = g1h->bot()->address_for_index(card_index);
tty->print_cr(" Card " PTR_FORMAT ".", p2i(card_start));
sum++;
}
guarantee(sum == 11 - 3 + 2048, "Failure");
guarantee(sum == hrrs->occupied(), "Failure");
}
#endif