6484956: G1: improve evacuation pause efficiency
Summary: A bunch of performance optimizations to decrease GC pause times in G1.
Reviewed-by: apetrusenko, jmasa, iveresov
/*
* Copyright 2001-2008 Sun Microsystems, Inc. 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 Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
* CA 95054 USA or visit www.sun.com if you need additional information or
* have any questions.
*
*/
#ifndef SERIALGC
// A HeapRegion is the smallest piece of a G1CollectedHeap that
// can be collected independently.
// NOTE: Although a HeapRegion is a Space, its
// Space::initDirtyCardClosure method must not be called.
// The problem is that the existence of this method breaks
// the independence of barrier sets from remembered sets.
// The solution is to remove this method from the definition
// of a Space.
class CompactibleSpace;
class ContiguousSpace;
class HeapRegionRemSet;
class HeapRegionRemSetIterator;
class HeapRegion;
// A dirty card to oop closure for heap regions. It
// knows how to get the G1 heap and how to use the bitmap
// in the concurrent marker used by G1 to filter remembered
// sets.
class HeapRegionDCTOC : public ContiguousSpaceDCTOC {
public:
// Specification of possible DirtyCardToOopClosure filtering.
enum FilterKind {
NoFilterKind,
IntoCSFilterKind,
OutOfRegionFilterKind
};
protected:
HeapRegion* _hr;
FilterKind _fk;
G1CollectedHeap* _g1;
void walk_mem_region_with_cl(MemRegion mr,
HeapWord* bottom, HeapWord* top,
OopClosure* cl);
// We don't specialize this for FilteringClosure; filtering is handled by
// the "FilterKind" mechanism. But we provide this to avoid a compiler
// warning.
void walk_mem_region_with_cl(MemRegion mr,
HeapWord* bottom, HeapWord* top,
FilteringClosure* cl) {
HeapRegionDCTOC::walk_mem_region_with_cl(mr, bottom, top,
(OopClosure*)cl);
}
// Get the actual top of the area on which the closure will
// operate, given where the top is assumed to be (the end of the
// memory region passed to do_MemRegion) and where the object
// at the top is assumed to start. For example, an object may
// start at the top but actually extend past the assumed top,
// in which case the top becomes the end of the object.
HeapWord* get_actual_top(HeapWord* top, HeapWord* top_obj) {
return ContiguousSpaceDCTOC::get_actual_top(top, top_obj);
}
// Walk the given memory region from bottom to (actual) top
// looking for objects and applying the oop closure (_cl) to
// them. The base implementation of this treats the area as
// blocks, where a block may or may not be an object. Sub-
// classes should override this to provide more accurate
// or possibly more efficient walking.
void walk_mem_region(MemRegion mr, HeapWord* bottom, HeapWord* top) {
Filtering_DCTOC::walk_mem_region(mr, bottom, top);
}
public:
HeapRegionDCTOC(G1CollectedHeap* g1,
HeapRegion* hr, OopClosure* cl,
CardTableModRefBS::PrecisionStyle precision,
FilterKind fk);
};
// The complicating factor is that BlockOffsetTable diverged
// significantly, and we need functionality that is only in the G1 version.
// So I copied that code, which led to an alternate G1 version of
// OffsetTableContigSpace. If the two versions of BlockOffsetTable could
// be reconciled, then G1OffsetTableContigSpace could go away.
// The idea behind time stamps is the following. Doing a save_marks on
// all regions at every GC pause is time consuming (if I remember
// well, 10ms or so). So, we would like to do that only for regions
// that are GC alloc regions. To achieve this, we use time
// stamps. For every evacuation pause, G1CollectedHeap generates a
// unique time stamp (essentially a counter that gets
// incremented). Every time we want to call save_marks on a region,
// we set the saved_mark_word to top and also copy the current GC
// time stamp to the time stamp field of the space. Reading the
// saved_mark_word involves checking the time stamp of the
// region. If it is the same as the current GC time stamp, then we
// can safely read the saved_mark_word field, as it is valid. If the
// time stamp of the region is not the same as the current GC time
// stamp, then we instead read top, as the saved_mark_word field is
// invalid. Time stamps (on the regions and also on the
// G1CollectedHeap) are reset at every cleanup (we iterate over
// the regions anyway) and at the end of a Full GC. The current scheme
// that uses sequential unsigned ints will fail only if we have 4b
// evacuation pauses between two cleanups, which is _highly_ unlikely.
class G1OffsetTableContigSpace: public ContiguousSpace {
friend class VMStructs;
protected:
G1BlockOffsetArrayContigSpace _offsets;
Mutex _par_alloc_lock;
volatile unsigned _gc_time_stamp;
public:
// Constructor. If "is_zeroed" is true, the MemRegion "mr" may be
// assumed to contain zeros.
G1OffsetTableContigSpace(G1BlockOffsetSharedArray* sharedOffsetArray,
MemRegion mr, bool is_zeroed = false);
void set_bottom(HeapWord* value);
void set_end(HeapWord* value);
virtual HeapWord* saved_mark_word() const;
virtual void set_saved_mark();
void reset_gc_time_stamp() { _gc_time_stamp = 0; }
virtual void initialize(MemRegion mr, bool clear_space, bool mangle_space);
virtual void clear(bool mangle_space);
HeapWord* block_start(const void* p);
HeapWord* block_start_const(const void* p) const;
// Add offset table update.
virtual HeapWord* allocate(size_t word_size);
HeapWord* par_allocate(size_t word_size);
// MarkSweep support phase3
virtual HeapWord* initialize_threshold();
virtual HeapWord* cross_threshold(HeapWord* start, HeapWord* end);
virtual void print() const;
};
class HeapRegion: public G1OffsetTableContigSpace {
friend class VMStructs;
private:
enum HumongousType {
NotHumongous = 0,
StartsHumongous,
ContinuesHumongous
};
// The next filter kind that should be used for a "new_dcto_cl" call with
// the "traditional" signature.
HeapRegionDCTOC::FilterKind _next_fk;
// Requires that the region "mr" be dense with objects, and begin and end
// with an object.
void oops_in_mr_iterate(MemRegion mr, OopClosure* cl);
// The remembered set for this region.
// (Might want to make this "inline" later, to avoid some alloc failure
// issues.)
HeapRegionRemSet* _rem_set;
G1BlockOffsetArrayContigSpace* offsets() { return &_offsets; }
protected:
// If this region is a member of a HeapRegionSeq, the index in that
// sequence, otherwise -1.
int _hrs_index;
HumongousType _humongous_type;
// For a humongous region, region in which it starts.
HeapRegion* _humongous_start_region;
// For the start region of a humongous sequence, it's original end().
HeapWord* _orig_end;
// True iff the region is in current collection_set.
bool _in_collection_set;
// True iff the region is on the unclean list, waiting to be zero filled.
bool _is_on_unclean_list;
// True iff the region is on the free list, ready for allocation.
bool _is_on_free_list;
// Is this or has it been an allocation region in the current collection
// pause.
bool _is_gc_alloc_region;
// True iff an attempt to evacuate an object in the region failed.
bool _evacuation_failed;
// A heap region may be a member one of a number of special subsets, each
// represented as linked lists through the field below. Currently, these
// sets include:
// The collection set.
// The set of allocation regions used in a collection pause.
// Spaces that may contain gray objects.
HeapRegion* _next_in_special_set;
// next region in the young "generation" region set
HeapRegion* _next_young_region;
// For parallel heapRegion traversal.
jint _claimed;
// We use concurrent marking to determine the amount of live data
// in each heap region.
size_t _prev_marked_bytes; // Bytes known to be live via last completed marking.
size_t _next_marked_bytes; // Bytes known to be live via in-progress marking.
// See "sort_index" method. -1 means is not in the array.
int _sort_index;
// Means it has (or at least had) a very large RS, and should not be
// considered for membership in a collection set.
enum PopularityState {
NotPopular,
PopularPending,
Popular
};
PopularityState _popularity;
// <PREDICTION>
double _gc_efficiency;
// </PREDICTION>
enum YoungType {
NotYoung, // a region is not young
ScanOnly, // a region is young and scan-only
Young, // a region is young
Survivor // a region is young and it contains
// survivor
};
YoungType _young_type;
int _young_index_in_cset;
SurvRateGroup* _surv_rate_group;
int _age_index;
// The start of the unmarked area. The unmarked area extends from this
// word until the top and/or end of the region, and is the part
// of the region for which no marking was done, i.e. objects may
// have been allocated in this part since the last mark phase.
// "prev" is the top at the start of the last completed marking.
// "next" is the top at the start of the in-progress marking (if any.)
HeapWord* _prev_top_at_mark_start;
HeapWord* _next_top_at_mark_start;
// If a collection pause is in progress, this is the top at the start
// of that pause.
// We've counted the marked bytes of objects below here.
HeapWord* _top_at_conc_mark_count;
void init_top_at_mark_start() {
assert(_prev_marked_bytes == 0 &&
_next_marked_bytes == 0,
"Must be called after zero_marked_bytes.");
HeapWord* bot = bottom();
_prev_top_at_mark_start = bot;
_next_top_at_mark_start = bot;
_top_at_conc_mark_count = bot;
}
jint _zfs; // A member of ZeroFillState. Protected by ZF_lock.
Thread* _zero_filler; // If _zfs is ZeroFilling, the thread that (last)
// made it so.
void set_young_type(YoungType new_type) {
//assert(_young_type != new_type, "setting the same type" );
// TODO: add more assertions here
_young_type = new_type;
}
public:
// If "is_zeroed" is "true", the region "mr" can be assumed to contain zeros.
HeapRegion(G1BlockOffsetSharedArray* sharedOffsetArray,
MemRegion mr, bool is_zeroed);
enum SomePublicConstants {
// HeapRegions are GrainBytes-aligned
// and have sizes that are multiples of GrainBytes.
LogOfHRGrainBytes = 20,
LogOfHRGrainWords = LogOfHRGrainBytes - LogHeapWordSize,
GrainBytes = 1 << LogOfHRGrainBytes,
GrainWords = 1 <<LogOfHRGrainWords,
MaxAge = 2, NoOfAges = MaxAge+1
};
enum ClaimValues {
InitialClaimValue = 0,
FinalCountClaimValue = 1,
NoteEndClaimValue = 2,
ScrubRemSetClaimValue = 3,
ParVerifyClaimValue = 4
};
// Concurrent refinement requires contiguous heap regions (in which TLABs
// might be allocated) to be zero-filled. Each region therefore has a
// zero-fill-state.
enum ZeroFillState {
NotZeroFilled,
ZeroFilling,
ZeroFilled,
Allocated
};
// If this region is a member of a HeapRegionSeq, the index in that
// sequence, otherwise -1.
int hrs_index() const { return _hrs_index; }
void set_hrs_index(int index) { _hrs_index = index; }
// The number of bytes marked live in the region in the last marking phase.
size_t marked_bytes() { return _prev_marked_bytes; }
// The number of bytes counted in the next marking.
size_t next_marked_bytes() { return _next_marked_bytes; }
// The number of bytes live wrt the next marking.
size_t next_live_bytes() {
return (top() - next_top_at_mark_start())
* HeapWordSize
+ next_marked_bytes();
}
// A lower bound on the amount of garbage bytes in the region.
size_t garbage_bytes() {
size_t used_at_mark_start_bytes =
(prev_top_at_mark_start() - bottom()) * HeapWordSize;
assert(used_at_mark_start_bytes >= marked_bytes(),
"Can't mark more than we have.");
return used_at_mark_start_bytes - marked_bytes();
}
// An upper bound on the number of live bytes in the region.
size_t max_live_bytes() { return used() - garbage_bytes(); }
void add_to_marked_bytes(size_t incr_bytes) {
_next_marked_bytes = _next_marked_bytes + incr_bytes;
guarantee( _next_marked_bytes <= used(), "invariant" );
}
void zero_marked_bytes() {
_prev_marked_bytes = _next_marked_bytes = 0;
}
bool isHumongous() const { return _humongous_type != NotHumongous; }
bool startsHumongous() const { return _humongous_type == StartsHumongous; }
bool continuesHumongous() const { return _humongous_type == ContinuesHumongous; }
// For a humongous region, region in which it starts.
HeapRegion* humongous_start_region() const {
return _humongous_start_region;
}
// Causes the current region to represent a humongous object spanning "n"
// regions.
virtual void set_startsHumongous();
// The regions that continue a humongous sequence should be added using
// this method, in increasing address order.
void set_continuesHumongous(HeapRegion* start);
void add_continuingHumongousRegion(HeapRegion* cont);
// If the region has a remembered set, return a pointer to it.
HeapRegionRemSet* rem_set() const {
return _rem_set;
}
// True iff the region is in current collection_set.
bool in_collection_set() const {
return _in_collection_set;
}
void set_in_collection_set(bool b) {
_in_collection_set = b;
}
HeapRegion* next_in_collection_set() {
assert(in_collection_set(), "should only invoke on member of CS.");
assert(_next_in_special_set == NULL ||
_next_in_special_set->in_collection_set(),
"Malformed CS.");
return _next_in_special_set;
}
void set_next_in_collection_set(HeapRegion* r) {
assert(in_collection_set(), "should only invoke on member of CS.");
assert(r == NULL || r->in_collection_set(), "Malformed CS.");
_next_in_special_set = r;
}
// True iff it is or has been an allocation region in the current
// collection pause.
bool is_gc_alloc_region() const {
return _is_gc_alloc_region;
}
void set_is_gc_alloc_region(bool b) {
_is_gc_alloc_region = b;
}
HeapRegion* next_gc_alloc_region() {
assert(is_gc_alloc_region(), "should only invoke on member of CS.");
assert(_next_in_special_set == NULL ||
_next_in_special_set->is_gc_alloc_region(),
"Malformed CS.");
return _next_in_special_set;
}
void set_next_gc_alloc_region(HeapRegion* r) {
assert(is_gc_alloc_region(), "should only invoke on member of CS.");
assert(r == NULL || r->is_gc_alloc_region(), "Malformed CS.");
_next_in_special_set = r;
}
bool is_reserved() {
return popular();
}
bool is_on_free_list() {
return _is_on_free_list;
}
void set_on_free_list(bool b) {
_is_on_free_list = b;
}
HeapRegion* next_from_free_list() {
assert(is_on_free_list(),
"Should only invoke on free space.");
assert(_next_in_special_set == NULL ||
_next_in_special_set->is_on_free_list(),
"Malformed Free List.");
return _next_in_special_set;
}
void set_next_on_free_list(HeapRegion* r) {
assert(r == NULL || r->is_on_free_list(), "Malformed free list.");
_next_in_special_set = r;
}
bool is_on_unclean_list() {
return _is_on_unclean_list;
}
void set_on_unclean_list(bool b);
HeapRegion* next_from_unclean_list() {
assert(is_on_unclean_list(),
"Should only invoke on unclean space.");
assert(_next_in_special_set == NULL ||
_next_in_special_set->is_on_unclean_list(),
"Malformed unclean List.");
return _next_in_special_set;
}
void set_next_on_unclean_list(HeapRegion* r);
HeapRegion* get_next_young_region() { return _next_young_region; }
void set_next_young_region(HeapRegion* hr) {
_next_young_region = hr;
}
// Allows logical separation between objects allocated before and after.
void save_marks();
// Reset HR stuff to default values.
void hr_clear(bool par, bool clear_space);
void initialize(MemRegion mr, bool clear_space, bool mangle_space);
// Ensure that "this" is zero-filled.
void ensure_zero_filled();
// This one requires that the calling thread holds ZF_mon.
void ensure_zero_filled_locked();
// Get the start of the unmarked area in this region.
HeapWord* prev_top_at_mark_start() const { return _prev_top_at_mark_start; }
HeapWord* next_top_at_mark_start() const { return _next_top_at_mark_start; }
// Apply "cl->do_oop" to (the addresses of) all reference fields in objects
// allocated in the current region before the last call to "save_mark".
void oop_before_save_marks_iterate(OopClosure* cl);
// This call determines the "filter kind" argument that will be used for
// the next call to "new_dcto_cl" on this region with the "traditional"
// signature (i.e., the call below.) The default, in the absence of a
// preceding call to this method, is "NoFilterKind", and a call to this
// method is necessary for each such call, or else it reverts to the
// default.
// (This is really ugly, but all other methods I could think of changed a
// lot of main-line code for G1.)
void set_next_filter_kind(HeapRegionDCTOC::FilterKind nfk) {
_next_fk = nfk;
}
DirtyCardToOopClosure*
new_dcto_closure(OopClosure* cl,
CardTableModRefBS::PrecisionStyle precision,
HeapRegionDCTOC::FilterKind fk);
#if WHASSUP
DirtyCardToOopClosure*
new_dcto_closure(OopClosure* cl,
CardTableModRefBS::PrecisionStyle precision,
HeapWord* boundary) {
assert(boundary == NULL, "This arg doesn't make sense here.");
DirtyCardToOopClosure* res = new_dcto_closure(cl, precision, _next_fk);
_next_fk = HeapRegionDCTOC::NoFilterKind;
return res;
}
#endif
//
// Note the start or end of marking. This tells the heap region
// that the collector is about to start or has finished (concurrently)
// marking the heap.
//
// Note the start of a marking phase. Record the
// start of the unmarked area of the region here.
void note_start_of_marking(bool during_initial_mark) {
init_top_at_conc_mark_count();
_next_marked_bytes = 0;
if (during_initial_mark && is_young() && !is_survivor())
_next_top_at_mark_start = bottom();
else
_next_top_at_mark_start = top();
}
// Note the end of a marking phase. Install the start of
// the unmarked area that was captured at start of marking.
void note_end_of_marking() {
_prev_top_at_mark_start = _next_top_at_mark_start;
_prev_marked_bytes = _next_marked_bytes;
_next_marked_bytes = 0;
guarantee(_prev_marked_bytes <=
(size_t) (prev_top_at_mark_start() - bottom()) * HeapWordSize,
"invariant");
}
// After an evacuation, we need to update _next_top_at_mark_start
// to be the current top. Note this is only valid if we have only
// ever evacuated into this region. If we evacuate, allocate, and
// then evacuate we are in deep doodoo.
void note_end_of_copying() {
assert(top() >= _next_top_at_mark_start,
"Increase only");
_next_top_at_mark_start = top();
}
// Returns "false" iff no object in the region was allocated when the
// last mark phase ended.
bool is_marked() { return _prev_top_at_mark_start != bottom(); }
// If "is_marked()" is true, then this is the index of the region in
// an array constructed at the end of marking of the regions in a
// "desirability" order.
int sort_index() {
return _sort_index;
}
void set_sort_index(int i) {
_sort_index = i;
}
void init_top_at_conc_mark_count() {
_top_at_conc_mark_count = bottom();
}
void set_top_at_conc_mark_count(HeapWord *cur) {
assert(bottom() <= cur && cur <= end(), "Sanity.");
_top_at_conc_mark_count = cur;
}
HeapWord* top_at_conc_mark_count() {
return _top_at_conc_mark_count;
}
void reset_during_compaction() {
guarantee( isHumongous() && startsHumongous(),
"should only be called for humongous regions");
zero_marked_bytes();
init_top_at_mark_start();
}
bool popular() { return _popularity == Popular; }
void set_popular(bool b) {
if (b) {
_popularity = Popular;
} else {
_popularity = NotPopular;
}
}
bool popular_pending() { return _popularity == PopularPending; }
void set_popular_pending(bool b) {
if (b) {
_popularity = PopularPending;
} else {
_popularity = NotPopular;
}
}
// <PREDICTION>
void calc_gc_efficiency(void);
double gc_efficiency() { return _gc_efficiency;}
// </PREDICTION>
bool is_young() const { return _young_type != NotYoung; }
bool is_scan_only() const { return _young_type == ScanOnly; }
bool is_survivor() const { return _young_type == Survivor; }
int young_index_in_cset() const { return _young_index_in_cset; }
void set_young_index_in_cset(int index) {
assert( (index == -1) || is_young(), "pre-condition" );
_young_index_in_cset = index;
}
int age_in_surv_rate_group() {
assert( _surv_rate_group != NULL, "pre-condition" );
assert( _age_index > -1, "pre-condition" );
return _surv_rate_group->age_in_group(_age_index);
}
void recalculate_age_in_surv_rate_group() {
assert( _surv_rate_group != NULL, "pre-condition" );
assert( _age_index > -1, "pre-condition" );
_age_index = _surv_rate_group->recalculate_age_index(_age_index);
}
void record_surv_words_in_group(size_t words_survived) {
assert( _surv_rate_group != NULL, "pre-condition" );
assert( _age_index > -1, "pre-condition" );
int age_in_group = age_in_surv_rate_group();
_surv_rate_group->record_surviving_words(age_in_group, words_survived);
}
int age_in_surv_rate_group_cond() {
if (_surv_rate_group != NULL)
return age_in_surv_rate_group();
else
return -1;
}
SurvRateGroup* surv_rate_group() {
return _surv_rate_group;
}
void install_surv_rate_group(SurvRateGroup* surv_rate_group) {
assert( surv_rate_group != NULL, "pre-condition" );
assert( _surv_rate_group == NULL, "pre-condition" );
assert( is_young(), "pre-condition" );
_surv_rate_group = surv_rate_group;
_age_index = surv_rate_group->next_age_index();
}
void uninstall_surv_rate_group() {
if (_surv_rate_group != NULL) {
assert( _age_index > -1, "pre-condition" );
assert( is_young(), "pre-condition" );
_surv_rate_group = NULL;
_age_index = -1;
} else {
assert( _age_index == -1, "pre-condition" );
}
}
void set_young() { set_young_type(Young); }
void set_scan_only() { set_young_type(ScanOnly); }
void set_survivor() { set_young_type(Survivor); }
void set_not_young() { set_young_type(NotYoung); }
// Determine if an object has been allocated since the last
// mark performed by the collector. This returns true iff the object
// is within the unmarked area of the region.
bool obj_allocated_since_prev_marking(oop obj) const {
return (HeapWord *) obj >= prev_top_at_mark_start();
}
bool obj_allocated_since_next_marking(oop obj) const {
return (HeapWord *) obj >= next_top_at_mark_start();
}
// For parallel heapRegion traversal.
bool claimHeapRegion(int claimValue);
jint claim_value() { return _claimed; }
// Use this carefully: only when you're sure no one is claiming...
void set_claim_value(int claimValue) { _claimed = claimValue; }
// Returns the "evacuation_failed" property of the region.
bool evacuation_failed() { return _evacuation_failed; }
// Sets the "evacuation_failed" property of the region.
void set_evacuation_failed(bool b) {
_evacuation_failed = b;
if (b) {
init_top_at_conc_mark_count();
_next_marked_bytes = 0;
}
}
// Requires that "mr" be entirely within the region.
// Apply "cl->do_object" to all objects that intersect with "mr".
// If the iteration encounters an unparseable portion of the region,
// or if "cl->abort()" is true after a closure application,
// terminate the iteration and return the address of the start of the
// subregion that isn't done. (The two can be distinguished by querying
// "cl->abort()".) Return of "NULL" indicates that the iteration
// completed.
HeapWord*
object_iterate_mem_careful(MemRegion mr, ObjectClosure* cl);
HeapWord*
oops_on_card_seq_iterate_careful(MemRegion mr,
FilterOutOfRegionClosure* cl);
// The region "mr" is entirely in "this", and starts and ends at block
// boundaries. The caller declares that all the contained blocks are
// coalesced into one.
void declare_filled_region_to_BOT(MemRegion mr) {
_offsets.single_block(mr.start(), mr.end());
}
// A version of block start that is guaranteed to find *some* block
// boundary at or before "p", but does not object iteration, and may
// therefore be used safely when the heap is unparseable.
HeapWord* block_start_careful(const void* p) const {
return _offsets.block_start_careful(p);
}
// Requires that "addr" is within the region. Returns the start of the
// first ("careful") block that starts at or after "addr", or else the
// "end" of the region if there is no such block.
HeapWord* next_block_start_careful(HeapWord* addr);
// Returns the zero-fill-state of the current region.
ZeroFillState zero_fill_state() { return (ZeroFillState)_zfs; }
bool zero_fill_is_allocated() { return _zfs == Allocated; }
Thread* zero_filler() { return _zero_filler; }
// Indicate that the contents of the region are unknown, and therefore
// might require zero-filling.
void set_zero_fill_needed() {
set_zero_fill_state_work(NotZeroFilled);
}
void set_zero_fill_in_progress(Thread* t) {
set_zero_fill_state_work(ZeroFilling);
_zero_filler = t;
}
void set_zero_fill_complete();
void set_zero_fill_allocated() {
set_zero_fill_state_work(Allocated);
}
void set_zero_fill_state_work(ZeroFillState zfs);
// This is called when a full collection shrinks the heap.
// We want to set the heap region to a value which says
// it is no longer part of the heap. For now, we'll let "NotZF" fill
// that role.
void reset_zero_fill() {
set_zero_fill_state_work(NotZeroFilled);
_zero_filler = NULL;
}
#define HeapRegion_OOP_SINCE_SAVE_MARKS_DECL(OopClosureType, nv_suffix) \
virtual void oop_since_save_marks_iterate##nv_suffix(OopClosureType* cl);
SPECIALIZED_SINCE_SAVE_MARKS_CLOSURES(HeapRegion_OOP_SINCE_SAVE_MARKS_DECL)
CompactibleSpace* next_compaction_space() const;
virtual void reset_after_compaction();
void print() const;
void print_on(outputStream* st) const;
// Override
virtual void verify(bool allow_dirty) const;
#ifdef DEBUG
HeapWord* allocate(size_t size);
#endif
};
// HeapRegionClosure is used for iterating over regions.
// Terminates the iteration when the "doHeapRegion" method returns "true".
class HeapRegionClosure : public StackObj {
friend class HeapRegionSeq;
friend class G1CollectedHeap;
bool _complete;
void incomplete() { _complete = false; }
public:
HeapRegionClosure(): _complete(true) {}
// Typically called on each region until it returns true.
virtual bool doHeapRegion(HeapRegion* r) = 0;
// True after iteration if the closure was applied to all heap regions
// and returned "false" in all cases.
bool complete() { return _complete; }
};
// A linked lists of heap regions. It leaves the "next" field
// unspecified; that's up to subtypes.
class RegionList {
protected:
virtual HeapRegion* get_next(HeapRegion* chr) = 0;
virtual void set_next(HeapRegion* chr,
HeapRegion* new_next) = 0;
HeapRegion* _hd;
HeapRegion* _tl;
size_t _sz;
// Protected constructor because this type is only meaningful
// when the _get/_set next functions are defined.
RegionList() : _hd(NULL), _tl(NULL), _sz(0) {}
public:
void reset() {
_hd = NULL;
_tl = NULL;
_sz = 0;
}
HeapRegion* hd() { return _hd; }
HeapRegion* tl() { return _tl; }
size_t sz() { return _sz; }
size_t length();
bool well_formed() {
return
((hd() == NULL && tl() == NULL && sz() == 0)
|| (hd() != NULL && tl() != NULL && sz() > 0))
&& (sz() == length());
}
virtual void insert_before_head(HeapRegion* r);
void prepend_list(RegionList* new_list);
virtual HeapRegion* pop();
void dec_sz() { _sz--; }
// Requires that "r" is an element of the list, and is not the tail.
void delete_after(HeapRegion* r);
};
class EmptyNonHRegionList: public RegionList {
protected:
// Protected constructor because this type is only meaningful
// when the _get/_set next functions are defined.
EmptyNonHRegionList() : RegionList() {}
public:
void insert_before_head(HeapRegion* r) {
// assert(r->is_empty(), "Better be empty");
assert(!r->isHumongous(), "Better not be humongous.");
RegionList::insert_before_head(r);
}
void prepend_list(EmptyNonHRegionList* new_list) {
// assert(new_list->hd() == NULL || new_list->hd()->is_empty(),
// "Better be empty");
assert(new_list->hd() == NULL || !new_list->hd()->isHumongous(),
"Better not be humongous.");
// assert(new_list->tl() == NULL || new_list->tl()->is_empty(),
// "Better be empty");
assert(new_list->tl() == NULL || !new_list->tl()->isHumongous(),
"Better not be humongous.");
RegionList::prepend_list(new_list);
}
};
class UncleanRegionList: public EmptyNonHRegionList {
public:
HeapRegion* get_next(HeapRegion* hr) {
return hr->next_from_unclean_list();
}
void set_next(HeapRegion* hr, HeapRegion* new_next) {
hr->set_next_on_unclean_list(new_next);
}
UncleanRegionList() : EmptyNonHRegionList() {}
void insert_before_head(HeapRegion* r) {
assert(!r->is_on_free_list(),
"Better not already be on free list");
assert(!r->is_on_unclean_list(),
"Better not already be on unclean list");
r->set_zero_fill_needed();
r->set_on_unclean_list(true);
EmptyNonHRegionList::insert_before_head(r);
}
void prepend_list(UncleanRegionList* new_list) {
assert(new_list->tl() == NULL || !new_list->tl()->is_on_free_list(),
"Better not already be on free list");
assert(new_list->tl() == NULL || new_list->tl()->is_on_unclean_list(),
"Better already be marked as on unclean list");
assert(new_list->hd() == NULL || !new_list->hd()->is_on_free_list(),
"Better not already be on free list");
assert(new_list->hd() == NULL || new_list->hd()->is_on_unclean_list(),
"Better already be marked as on unclean list");
EmptyNonHRegionList::prepend_list(new_list);
}
HeapRegion* pop() {
HeapRegion* res = RegionList::pop();
if (res != NULL) res->set_on_unclean_list(false);
return res;
}
};
// Local Variables: ***
// c-indentation-style: gnu ***
// End: ***
#endif // SERIALGC