1 // Copyright 2012 the V8 project authors. All rights reserved. 2 // Use of this source code is governed by a BSD-style license that can be 3 // found in the LICENSE file. 4 5 #ifndef V8_HEAP_MARK_COMPACT_H_ 6 #define V8_HEAP_MARK_COMPACT_H_ 7 8 #include <deque> 9 10 #include "src/base/bits.h" 11 #include "src/base/platform/condition-variable.h" 12 #include "src/cancelable-task.h" 13 #include "src/heap/marking.h" 14 #include "src/heap/spaces.h" 15 #include "src/heap/store-buffer.h" 16 17 namespace v8 { 18 namespace internal { 19 20 enum class MarkCompactMode { FULL, YOUNG_GENERATION }; 21 22 // Callback function, returns whether an object is alive. The heap size 23 // of the object is returned in size. It optionally updates the offset 24 // to the first live object in the page (only used for old and map objects). 25 typedef bool (*IsAliveFunction)(HeapObject* obj, int* size, int* offset); 26 27 // Callback function to mark an object in a given heap. 28 typedef void (*MarkObjectFunction)(Heap* heap, HeapObject* object); 29 30 // Forward declarations. 31 class CodeFlusher; 32 class MarkCompactCollector; 33 class MarkingVisitor; 34 template <MarkCompactMode mode> 35 class RootMarkingVisitor; 36 37 class ObjectMarking : public AllStatic { 38 public: MarkBitFrom(HeapObject * obj)39 V8_INLINE static MarkBit MarkBitFrom(HeapObject* obj) { 40 const Address address = obj->address(); 41 MemoryChunk* p = MemoryChunk::FromAddress(address); 42 return p->markbits()->MarkBitFromIndex(p->AddressToMarkbitIndex(address)); 43 } 44 Color(HeapObject * obj)45 static Marking::ObjectColor Color(HeapObject* obj) { 46 return Marking::Color(ObjectMarking::MarkBitFrom(obj)); 47 } 48 IsImpossible(HeapObject * obj)49 V8_INLINE static bool IsImpossible(HeapObject* obj) { 50 return Marking::IsImpossible(MarkBitFrom(obj)); 51 } 52 IsBlack(HeapObject * obj)53 V8_INLINE static bool IsBlack(HeapObject* obj) { 54 return Marking::IsBlack(MarkBitFrom(obj)); 55 } 56 IsWhite(HeapObject * obj)57 V8_INLINE static bool IsWhite(HeapObject* obj) { 58 return Marking::IsWhite(MarkBitFrom(obj)); 59 } 60 IsGrey(HeapObject * obj)61 V8_INLINE static bool IsGrey(HeapObject* obj) { 62 return Marking::IsGrey(MarkBitFrom(obj)); 63 } 64 IsBlackOrGrey(HeapObject * obj)65 V8_INLINE static bool IsBlackOrGrey(HeapObject* obj) { 66 return Marking::IsBlackOrGrey(MarkBitFrom(obj)); 67 } 68 ClearMarkBit(HeapObject * obj)69 V8_INLINE static void ClearMarkBit(HeapObject* obj) { 70 Marking::MarkWhite(MarkBitFrom(obj)); 71 } 72 BlackToWhite(HeapObject * obj)73 V8_INLINE static void BlackToWhite(HeapObject* obj) { 74 DCHECK(IsBlack(obj)); 75 MarkBit markbit = MarkBitFrom(obj); 76 Marking::BlackToWhite(markbit); 77 MemoryChunk::IncrementLiveBytes(obj, -obj->Size()); 78 } 79 GreyToWhite(HeapObject * obj)80 V8_INLINE static void GreyToWhite(HeapObject* obj) { 81 DCHECK(IsGrey(obj)); 82 Marking::GreyToWhite(MarkBitFrom(obj)); 83 } 84 BlackToGrey(HeapObject * obj)85 V8_INLINE static void BlackToGrey(HeapObject* obj) { 86 DCHECK(IsBlack(obj)); 87 MarkBit markbit = MarkBitFrom(obj); 88 Marking::BlackToGrey(markbit); 89 MemoryChunk::IncrementLiveBytes(obj, -obj->Size()); 90 } 91 WhiteToGrey(HeapObject * obj)92 V8_INLINE static void WhiteToGrey(HeapObject* obj) { 93 DCHECK(IsWhite(obj)); 94 Marking::WhiteToGrey(MarkBitFrom(obj)); 95 } 96 WhiteToBlack(HeapObject * obj)97 V8_INLINE static void WhiteToBlack(HeapObject* obj) { 98 DCHECK(IsWhite(obj)); 99 MarkBit markbit = MarkBitFrom(obj); 100 Marking::WhiteToBlack(markbit); 101 MemoryChunk::IncrementLiveBytes(obj, obj->Size()); 102 } 103 GreyToBlack(HeapObject * obj)104 V8_INLINE static void GreyToBlack(HeapObject* obj) { 105 DCHECK(IsGrey(obj)); 106 MarkBit markbit = MarkBitFrom(obj); 107 Marking::GreyToBlack(markbit); 108 MemoryChunk::IncrementLiveBytes(obj, obj->Size()); 109 } 110 AnyToGrey(HeapObject * obj)111 V8_INLINE static void AnyToGrey(HeapObject* obj) { 112 MarkBit markbit = MarkBitFrom(obj); 113 if (Marking::IsBlack(markbit)) { 114 MemoryChunk::IncrementLiveBytes(obj, -obj->Size()); 115 } 116 Marking::AnyToGrey(markbit); 117 } 118 119 private: 120 DISALLOW_IMPLICIT_CONSTRUCTORS(ObjectMarking); 121 }; 122 123 // ---------------------------------------------------------------------------- 124 // Marking deque for tracing live objects. 125 class MarkingDeque { 126 public: MarkingDeque(Heap * heap)127 explicit MarkingDeque(Heap* heap) 128 : backing_store_(nullptr), 129 backing_store_committed_size_(0), 130 array_(nullptr), 131 top_(0), 132 bottom_(0), 133 mask_(0), 134 overflowed_(false), 135 in_use_(false), 136 uncommit_task_pending_(false), 137 heap_(heap) {} 138 139 void SetUp(); 140 void TearDown(); 141 142 // Ensures that the marking deque is committed and will stay committed until 143 // StopUsing() is called. 144 void StartUsing(); 145 void StopUsing(); 146 void Clear(); 147 IsFull()148 inline bool IsFull() { return ((top_ + 1) & mask_) == bottom_; } 149 IsEmpty()150 inline bool IsEmpty() { return top_ == bottom_; } 151 overflowed()152 bool overflowed() const { return overflowed_; } 153 ClearOverflowed()154 void ClearOverflowed() { overflowed_ = false; } 155 SetOverflowed()156 void SetOverflowed() { overflowed_ = true; } 157 158 // Push the object on the marking stack if there is room, otherwise mark the 159 // deque as overflowed and wait for a rescan of the heap. INLINE(bool Push (HeapObject * object))160 INLINE(bool Push(HeapObject* object)) { 161 DCHECK(object->IsHeapObject()); 162 if (IsFull()) { 163 SetOverflowed(); 164 return false; 165 } else { 166 array_[top_] = object; 167 top_ = ((top_ + 1) & mask_); 168 return true; 169 } 170 } 171 INLINE(HeapObject * Pop ())172 INLINE(HeapObject* Pop()) { 173 DCHECK(!IsEmpty()); 174 top_ = ((top_ - 1) & mask_); 175 HeapObject* object = array_[top_]; 176 DCHECK(object->IsHeapObject()); 177 return object; 178 } 179 180 // Unshift the object into the marking stack if there is room, otherwise mark 181 // the deque as overflowed and wait for a rescan of the heap. INLINE(bool Unshift (HeapObject * object))182 INLINE(bool Unshift(HeapObject* object)) { 183 DCHECK(object->IsHeapObject()); 184 if (IsFull()) { 185 SetOverflowed(); 186 return false; 187 } else { 188 bottom_ = ((bottom_ - 1) & mask_); 189 array_[bottom_] = object; 190 return true; 191 } 192 } 193 array()194 HeapObject** array() { return array_; } bottom()195 int bottom() { return bottom_; } top()196 int top() { return top_; } mask()197 int mask() { return mask_; } set_top(int top)198 void set_top(int top) { top_ = top; } 199 200 private: 201 // This task uncommits the marking_deque backing store if 202 // markin_deque->in_use_ is false. 203 class UncommitTask : public CancelableTask { 204 public: UncommitTask(Isolate * isolate,MarkingDeque * marking_deque)205 explicit UncommitTask(Isolate* isolate, MarkingDeque* marking_deque) 206 : CancelableTask(isolate), marking_deque_(marking_deque) {} 207 208 private: 209 // CancelableTask override. RunInternal()210 void RunInternal() override { 211 base::LockGuard<base::Mutex> guard(&marking_deque_->mutex_); 212 if (!marking_deque_->in_use_) { 213 marking_deque_->Uncommit(); 214 } 215 marking_deque_->uncommit_task_pending_ = false; 216 } 217 218 MarkingDeque* marking_deque_; 219 DISALLOW_COPY_AND_ASSIGN(UncommitTask); 220 }; 221 222 static const size_t kMaxSize = 4 * MB; 223 static const size_t kMinSize = 256 * KB; 224 225 // Must be called with mutex lock. 226 void EnsureCommitted(); 227 228 // Must be called with mutex lock. 229 void Uncommit(); 230 231 // Must be called with mutex lock. 232 void StartUncommitTask(); 233 234 base::Mutex mutex_; 235 236 base::VirtualMemory* backing_store_; 237 size_t backing_store_committed_size_; 238 HeapObject** array_; 239 // array_[(top - 1) & mask_] is the top element in the deque. The Deque is 240 // empty when top_ == bottom_. It is full when top_ + 1 == bottom 241 // (mod mask + 1). 242 int top_; 243 int bottom_; 244 int mask_; 245 bool overflowed_; 246 // in_use_ == true after taking mutex lock implies that the marking deque is 247 // committed and will stay committed at least until in_use_ == false. 248 bool in_use_; 249 bool uncommit_task_pending_; 250 Heap* heap_; 251 252 DISALLOW_COPY_AND_ASSIGN(MarkingDeque); 253 }; 254 255 256 // CodeFlusher collects candidates for code flushing during marking and 257 // processes those candidates after marking has completed in order to 258 // reset those functions referencing code objects that would otherwise 259 // be unreachable. Code objects can be referenced in two ways: 260 // - SharedFunctionInfo references unoptimized code. 261 // - JSFunction references either unoptimized or optimized code. 262 // We are not allowed to flush unoptimized code for functions that got 263 // optimized or inlined into optimized code, because we might bailout 264 // into the unoptimized code again during deoptimization. 265 class CodeFlusher { 266 public: CodeFlusher(Isolate * isolate)267 explicit CodeFlusher(Isolate* isolate) 268 : isolate_(isolate), 269 jsfunction_candidates_head_(nullptr), 270 shared_function_info_candidates_head_(nullptr) {} 271 272 inline void AddCandidate(SharedFunctionInfo* shared_info); 273 inline void AddCandidate(JSFunction* function); 274 275 void EvictCandidate(SharedFunctionInfo* shared_info); 276 void EvictCandidate(JSFunction* function); 277 ProcessCandidates()278 void ProcessCandidates() { 279 ProcessSharedFunctionInfoCandidates(); 280 ProcessJSFunctionCandidates(); 281 } 282 283 void IteratePointersToFromSpace(ObjectVisitor* v); 284 285 private: 286 void ProcessJSFunctionCandidates(); 287 void ProcessSharedFunctionInfoCandidates(); 288 289 static inline JSFunction** GetNextCandidateSlot(JSFunction* candidate); 290 static inline JSFunction* GetNextCandidate(JSFunction* candidate); 291 static inline void SetNextCandidate(JSFunction* candidate, 292 JSFunction* next_candidate); 293 static inline void ClearNextCandidate(JSFunction* candidate, 294 Object* undefined); 295 296 static inline SharedFunctionInfo* GetNextCandidate( 297 SharedFunctionInfo* candidate); 298 static inline void SetNextCandidate(SharedFunctionInfo* candidate, 299 SharedFunctionInfo* next_candidate); 300 static inline void ClearNextCandidate(SharedFunctionInfo* candidate); 301 302 Isolate* isolate_; 303 JSFunction* jsfunction_candidates_head_; 304 SharedFunctionInfo* shared_function_info_candidates_head_; 305 306 DISALLOW_COPY_AND_ASSIGN(CodeFlusher); 307 }; 308 309 310 // Defined in isolate.h. 311 class ThreadLocalTop; 312 313 class MarkBitCellIterator BASE_EMBEDDED { 314 public: MarkBitCellIterator(MemoryChunk * chunk)315 explicit MarkBitCellIterator(MemoryChunk* chunk) : chunk_(chunk) { 316 last_cell_index_ = Bitmap::IndexToCell(Bitmap::CellAlignIndex( 317 chunk_->AddressToMarkbitIndex(chunk_->area_end()))); 318 cell_base_ = chunk_->area_start(); 319 cell_index_ = Bitmap::IndexToCell( 320 Bitmap::CellAlignIndex(chunk_->AddressToMarkbitIndex(cell_base_))); 321 cells_ = chunk_->markbits()->cells(); 322 } 323 Done()324 inline bool Done() { return cell_index_ == last_cell_index_; } 325 HasNext()326 inline bool HasNext() { return cell_index_ < last_cell_index_ - 1; } 327 CurrentCell()328 inline MarkBit::CellType* CurrentCell() { 329 DCHECK(cell_index_ == Bitmap::IndexToCell(Bitmap::CellAlignIndex( 330 chunk_->AddressToMarkbitIndex(cell_base_)))); 331 return &cells_[cell_index_]; 332 } 333 CurrentCellBase()334 inline Address CurrentCellBase() { 335 DCHECK(cell_index_ == Bitmap::IndexToCell(Bitmap::CellAlignIndex( 336 chunk_->AddressToMarkbitIndex(cell_base_)))); 337 return cell_base_; 338 } 339 Advance()340 inline void Advance() { 341 cell_index_++; 342 cell_base_ += Bitmap::kBitsPerCell * kPointerSize; 343 } 344 Advance(unsigned int new_cell_index)345 inline bool Advance(unsigned int new_cell_index) { 346 if (new_cell_index != cell_index_) { 347 DCHECK_GT(new_cell_index, cell_index_); 348 DCHECK_LE(new_cell_index, last_cell_index_); 349 unsigned int diff = new_cell_index - cell_index_; 350 cell_index_ = new_cell_index; 351 cell_base_ += diff * (Bitmap::kBitsPerCell * kPointerSize); 352 return true; 353 } 354 return false; 355 } 356 357 // Return the next mark bit cell. If there is no next it returns 0; PeekNext()358 inline MarkBit::CellType PeekNext() { 359 if (HasNext()) { 360 return cells_[cell_index_ + 1]; 361 } 362 return 0; 363 } 364 365 private: 366 MemoryChunk* chunk_; 367 MarkBit::CellType* cells_; 368 unsigned int last_cell_index_; 369 unsigned int cell_index_; 370 Address cell_base_; 371 }; 372 373 // Grey objects can happen on black pages when black objects transition to 374 // grey e.g. when calling RecordWrites on them. 375 enum LiveObjectIterationMode { 376 kBlackObjects, 377 kGreyObjects, 378 kAllLiveObjects 379 }; 380 381 template <LiveObjectIterationMode T> 382 class LiveObjectIterator BASE_EMBEDDED { 383 public: LiveObjectIterator(MemoryChunk * chunk)384 explicit LiveObjectIterator(MemoryChunk* chunk) 385 : chunk_(chunk), 386 it_(chunk_), 387 cell_base_(it_.CurrentCellBase()), 388 current_cell_(*it_.CurrentCell()) { 389 } 390 391 HeapObject* Next(); 392 393 private: heap()394 inline Heap* heap() { return chunk_->heap(); } 395 396 MemoryChunk* chunk_; 397 MarkBitCellIterator it_; 398 Address cell_base_; 399 MarkBit::CellType current_cell_; 400 }; 401 402 enum PageEvacuationMode { NEW_TO_NEW, NEW_TO_OLD }; 403 404 // ------------------------------------------------------------------------- 405 // Mark-Compact collector 406 class MarkCompactCollector { 407 public: 408 class Evacuator; 409 410 class Sweeper { 411 public: 412 class SweeperTask; 413 414 enum FreeListRebuildingMode { REBUILD_FREE_LIST, IGNORE_FREE_LIST }; 415 enum FreeSpaceTreatmentMode { IGNORE_FREE_SPACE, ZAP_FREE_SPACE }; 416 enum ClearOldToNewSlotsMode { 417 DO_NOT_CLEAR, 418 CLEAR_REGULAR_SLOTS, 419 CLEAR_TYPED_SLOTS 420 }; 421 422 typedef std::deque<Page*> SweepingList; 423 typedef List<Page*> SweptList; 424 425 static int RawSweep(Page* p, FreeListRebuildingMode free_list_mode, 426 FreeSpaceTreatmentMode free_space_mode); 427 Sweeper(Heap * heap)428 explicit Sweeper(Heap* heap) 429 : heap_(heap), 430 pending_sweeper_tasks_semaphore_(0), 431 sweeping_in_progress_(false), 432 num_sweeping_tasks_(0) {} 433 sweeping_in_progress()434 bool sweeping_in_progress() { return sweeping_in_progress_; } 435 436 void AddPage(AllocationSpace space, Page* page); 437 438 int ParallelSweepSpace(AllocationSpace identity, int required_freed_bytes, 439 int max_pages = 0); 440 int ParallelSweepPage(Page* page, AllocationSpace identity); 441 442 // After calling this function sweeping is considered to be in progress 443 // and the main thread can sweep lazily, but the background sweeper tasks 444 // are not running yet. 445 void StartSweeping(); 446 void StartSweeperTasks(); 447 void EnsureCompleted(); 448 void EnsureNewSpaceCompleted(); 449 bool AreSweeperTasksRunning(); 450 bool IsSweepingCompleted(AllocationSpace space); 451 void SweepOrWaitUntilSweepingCompleted(Page* page); 452 453 void AddSweptPageSafe(PagedSpace* space, Page* page); 454 Page* GetSweptPageSafe(PagedSpace* space); 455 456 private: 457 static const int kAllocationSpaces = LAST_PAGED_SPACE + 1; 458 459 static ClearOldToNewSlotsMode GetClearOldToNewSlotsMode(Page* p); 460 461 template <typename Callback> ForAllSweepingSpaces(Callback callback)462 void ForAllSweepingSpaces(Callback callback) { 463 for (int i = 0; i < kAllocationSpaces; i++) { 464 callback(static_cast<AllocationSpace>(i)); 465 } 466 } 467 468 Page* GetSweepingPageSafe(AllocationSpace space); 469 void AddSweepingPageSafe(AllocationSpace space, Page* page); 470 471 void PrepareToBeSweptPage(AllocationSpace space, Page* page); 472 473 Heap* heap_; 474 base::Semaphore pending_sweeper_tasks_semaphore_; 475 base::Mutex mutex_; 476 SweptList swept_list_[kAllocationSpaces]; 477 SweepingList sweeping_list_[kAllocationSpaces]; 478 bool sweeping_in_progress_; 479 base::AtomicNumber<intptr_t> num_sweeping_tasks_; 480 }; 481 482 enum IterationMode { 483 kKeepMarking, 484 kClearMarkbits, 485 }; 486 487 static void Initialize(); 488 489 static SlotCallbackResult CheckAndMarkObject(Heap* heap, 490 Address slot_address); 491 492 void SetUp(); 493 494 void TearDown(); 495 496 void CollectEvacuationCandidates(PagedSpace* space); 497 498 void AddEvacuationCandidate(Page* p); 499 500 // Prepares for GC by resetting relocation info in old and map spaces and 501 // choosing spaces to compact. 502 void Prepare(); 503 504 // Performs a global garbage collection. 505 void CollectGarbage(); 506 507 bool StartCompaction(); 508 509 void AbortCompaction(); 510 511 // Determine type of object and emit deletion log event. 512 static void ReportDeleteIfNeeded(HeapObject* obj, Isolate* isolate); 513 514 // Distinguishable invalid map encodings (for single word and multiple words) 515 // that indicate free regions. 516 static const uint32_t kSingleFreeEncoding = 0; 517 static const uint32_t kMultiFreeEncoding = 1; 518 519 static bool IsUnmarkedHeapObjectWithHeap(Heap* heap, Object** p); 520 heap()521 inline Heap* heap() const { return heap_; } 522 inline Isolate* isolate() const; 523 code_flusher()524 CodeFlusher* code_flusher() { return code_flusher_; } is_code_flushing_enabled()525 inline bool is_code_flushing_enabled() const { return code_flusher_ != NULL; } 526 INLINE(static bool ShouldSkipEvacuationSlotRecording (Object * host))527 INLINE(static bool ShouldSkipEvacuationSlotRecording(Object* host)) { 528 return Page::FromAddress(reinterpret_cast<Address>(host)) 529 ->ShouldSkipEvacuationSlotRecording(); 530 } 531 IsOnEvacuationCandidate(HeapObject * obj)532 static inline bool IsOnEvacuationCandidate(HeapObject* obj) { 533 return Page::FromAddress(reinterpret_cast<Address>(obj)) 534 ->IsEvacuationCandidate(); 535 } 536 537 void RecordRelocSlot(Code* host, RelocInfo* rinfo, Object* target); 538 void RecordCodeEntrySlot(HeapObject* host, Address slot, Code* target); 539 void RecordCodeTargetPatch(Address pc, Code* target); 540 INLINE(void RecordSlot(HeapObject* object, Object** slot, Object* target)); 541 INLINE(void ForceRecordSlot(HeapObject* object, Object** slot, 542 Object* target)); 543 void RecordLiveSlotsOnPage(Page* page); 544 545 void UpdateSlots(SlotsBuffer* buffer); 546 void UpdateSlotsRecordedIn(SlotsBuffer* buffer); 547 548 void InvalidateCode(Code* code); 549 550 void ClearMarkbits(); 551 is_compacting()552 bool is_compacting() const { return compacting_; } 553 554 // Ensures that sweeping is finished. 555 // 556 // Note: Can only be called safely from main thread. 557 void EnsureSweepingCompleted(); 558 559 // Help out in sweeping the corresponding space and refill memory that has 560 // been regained. 561 // 562 // Note: Thread-safe. 563 void SweepAndRefill(CompactionSpace* space); 564 565 // Checks if sweeping is in progress right now on any space. sweeping_in_progress()566 bool sweeping_in_progress() { return sweeper().sweeping_in_progress(); } 567 set_evacuation(bool evacuation)568 void set_evacuation(bool evacuation) { evacuation_ = evacuation; } 569 evacuation()570 bool evacuation() const { return evacuation_; } 571 572 // Mark objects in implicit references groups if their parent object 573 // is marked. 574 void MarkImplicitRefGroups(MarkObjectFunction mark_object); 575 marking_deque()576 MarkingDeque* marking_deque() { return &marking_deque_; } 577 sweeper()578 Sweeper& sweeper() { return sweeper_; } 579 580 #ifdef DEBUG 581 // Checks whether performing mark-compact collection. in_use()582 bool in_use() { return state_ > PREPARE_GC; } are_map_pointers_encoded()583 bool are_map_pointers_encoded() { return state_ == UPDATE_POINTERS; } 584 #endif 585 586 #ifdef VERIFY_HEAP 587 void VerifyValidStoreAndSlotsBufferEntries(); 588 void VerifyMarkbitsAreClean(); 589 static void VerifyMarkbitsAreClean(PagedSpace* space); 590 static void VerifyMarkbitsAreClean(NewSpace* space); 591 void VerifyWeakEmbeddedObjectsInCode(); 592 void VerifyOmittedMapChecks(); 593 #endif 594 595 private: 596 template <PageEvacuationMode mode> 597 class EvacuateNewSpacePageVisitor; 598 class EvacuateNewSpaceVisitor; 599 class EvacuateOldSpaceVisitor; 600 class EvacuateRecordOnlyVisitor; 601 class EvacuateVisitorBase; 602 class HeapObjectVisitor; 603 class ObjectStatsVisitor; 604 605 explicit MarkCompactCollector(Heap* heap); 606 607 bool WillBeDeoptimized(Code* code); 608 609 void ComputeEvacuationHeuristics(size_t area_size, 610 int* target_fragmentation_percent, 611 size_t* max_evacuated_bytes); 612 613 void VisitAllObjects(HeapObjectVisitor* visitor); 614 615 void RecordObjectStats(); 616 617 // Finishes GC, performs heap verification if enabled. 618 void Finish(); 619 620 // ----------------------------------------------------------------------- 621 // Phase 1: Marking live objects. 622 // 623 // Before: The heap has been prepared for garbage collection by 624 // MarkCompactCollector::Prepare() and is otherwise in its 625 // normal state. 626 // 627 // After: Live objects are marked and non-live objects are unmarked. 628 629 friend class CodeMarkingVisitor; 630 friend class IncrementalMarkingMarkingVisitor; 631 friend class MarkCompactMarkingVisitor; 632 friend class MarkingVisitor; 633 friend class RecordMigratedSlotVisitor; 634 template <MarkCompactMode mode> 635 friend class RootMarkingVisitor; 636 friend class SharedFunctionInfoMarkingVisitor; 637 friend class StaticYoungGenerationMarkingVisitor; 638 639 // Mark code objects that are active on the stack to prevent them 640 // from being flushed. 641 void PrepareThreadForCodeFlushing(Isolate* isolate, ThreadLocalTop* top); 642 643 void PrepareForCodeFlushing(); 644 645 // Marking operations for objects reachable from roots. 646 void MarkLiveObjects(); 647 // Mark the young generation. 648 void MarkLiveObjectsInYoungGeneration(); 649 650 // Pushes a black object onto the marking stack and accounts for live bytes. 651 // Note that this assumes live bytes have not yet been counted. 652 INLINE(void PushBlack(HeapObject* obj)); 653 654 // Unshifts a black object into the marking stack and accounts for live bytes. 655 // Note that this assumes lives bytes have already been counted. 656 INLINE(void UnshiftBlack(HeapObject* obj)); 657 658 // Marks the object black and pushes it on the marking stack. 659 // This is for non-incremental marking only. 660 INLINE(void MarkObject(HeapObject* obj)); 661 662 // Mark the heap roots and all objects reachable from them. 663 void MarkRoots(RootMarkingVisitor<MarkCompactMode::FULL>* visitor); 664 665 // Mark the string table specially. References to internalized strings from 666 // the string table are weak. 667 void MarkStringTable(RootMarkingVisitor<MarkCompactMode::FULL>* visitor); 668 669 // Mark objects reachable (transitively) from objects in the marking stack 670 // or overflowed in the heap. 671 template <MarkCompactMode mode> 672 void ProcessMarkingDeque(); 673 674 // Mark objects reachable (transitively) from objects in the marking stack 675 // or overflowed in the heap. This respects references only considered in 676 // the final atomic marking pause including the following: 677 // - Processing of objects reachable through Harmony WeakMaps. 678 // - Objects reachable due to host application logic like object groups, 679 // implicit references' groups, or embedder heap tracing. 680 void ProcessEphemeralMarking(ObjectVisitor* visitor, 681 bool only_process_harmony_weak_collections); 682 683 // If the call-site of the top optimized code was not prepared for 684 // deoptimization, then treat the maps in the code as strong pointers, 685 // otherwise a map can die and deoptimize the code. 686 void ProcessTopOptimizedFrame(ObjectVisitor* visitor); 687 688 // Collects a list of dependent code from maps embedded in optimize code. 689 DependentCode* DependentCodeListFromNonLiveMaps(); 690 691 // Mark objects reachable (transitively) from objects in the marking 692 // stack. This function empties the marking stack, but may leave 693 // overflowed objects in the heap, in which case the marking stack's 694 // overflow flag will be set. 695 template <MarkCompactMode mode> 696 void EmptyMarkingDeque(); 697 698 // Refill the marking stack with overflowed objects from the heap. This 699 // function either leaves the marking stack full or clears the overflow 700 // flag on the marking stack. 701 template <MarkCompactMode mode> 702 void RefillMarkingDeque(); 703 704 // Helper methods for refilling the marking stack by discovering grey objects 705 // on various pages of the heap. Used by {RefillMarkingDeque} only. 706 template <class T> 707 void DiscoverGreyObjectsWithIterator(T* it); 708 void DiscoverGreyObjectsOnPage(MemoryChunk* p); 709 void DiscoverGreyObjectsInSpace(PagedSpace* space); 710 void DiscoverGreyObjectsInNewSpace(); 711 712 // Callback function for telling whether the object *p is an unmarked 713 // heap object. 714 static bool IsUnmarkedHeapObject(Object** p); 715 716 // Clear non-live references in weak cells, transition and descriptor arrays, 717 // and deoptimize dependent code of non-live maps. 718 void ClearNonLiveReferences(); 719 void MarkDependentCodeForDeoptimization(DependentCode* list); 720 // Find non-live targets of simple transitions in the given list. Clear 721 // transitions to non-live targets and if needed trim descriptors arrays. 722 void ClearSimpleMapTransitions(Object* non_live_map_list); 723 void ClearSimpleMapTransition(Map* map, Map* dead_transition); 724 // Compact every array in the global list of transition arrays and 725 // trim the corresponding descriptor array if a transition target is non-live. 726 void ClearFullMapTransitions(); 727 bool CompactTransitionArray(Map* map, TransitionArray* transitions, 728 DescriptorArray* descriptors); 729 void TrimDescriptorArray(Map* map, DescriptorArray* descriptors); 730 void TrimEnumCache(Map* map, DescriptorArray* descriptors); 731 732 // Mark all values associated with reachable keys in weak collections 733 // encountered so far. This might push new object or even new weak maps onto 734 // the marking stack. 735 void ProcessWeakCollections(); 736 737 // After all reachable objects have been marked those weak map entries 738 // with an unreachable key are removed from all encountered weak maps. 739 // The linked list of all encountered weak maps is destroyed. 740 void ClearWeakCollections(); 741 742 // We have to remove all encountered weak maps from the list of weak 743 // collections when incremental marking is aborted. 744 void AbortWeakCollections(); 745 746 void ClearWeakCells(Object** non_live_map_list, 747 DependentCode** dependent_code_list); 748 void AbortWeakCells(); 749 750 void AbortTransitionArrays(); 751 752 // Starts sweeping of spaces by contributing on the main thread and setting 753 // up other pages for sweeping. Does not start sweeper tasks. 754 void StartSweepSpaces(); 755 void StartSweepSpace(PagedSpace* space); 756 757 void EvacuatePrologue(); 758 void EvacuateEpilogue(); 759 void EvacuatePagesInParallel(); 760 761 // The number of parallel compaction tasks, including the main thread. 762 int NumberOfParallelCompactionTasks(int pages, intptr_t live_bytes); 763 764 void EvacuateNewSpaceAndCandidates(); 765 766 void UpdatePointersAfterEvacuation(); 767 768 // Iterates through all live objects on a page using marking information. 769 // Returns whether all objects have successfully been visited. 770 template <class Visitor> 771 bool VisitLiveObjects(MemoryChunk* page, Visitor* visitor, 772 IterationMode mode); 773 774 void RecomputeLiveBytes(MemoryChunk* page); 775 776 void ReleaseEvacuationCandidates(); 777 778 779 #ifdef DEBUG 780 friend class MarkObjectVisitor; 781 static void VisitObject(HeapObject* obj); 782 783 friend class UnmarkObjectVisitor; 784 static void UnmarkObject(HeapObject* obj); 785 #endif 786 787 Heap* heap_; 788 789 base::Semaphore page_parallel_job_semaphore_; 790 791 #ifdef DEBUG 792 enum CollectorState { 793 IDLE, 794 PREPARE_GC, 795 MARK_LIVE_OBJECTS, 796 SWEEP_SPACES, 797 ENCODE_FORWARDING_ADDRESSES, 798 UPDATE_POINTERS, 799 RELOCATE_OBJECTS 800 }; 801 802 // The current stage of the collector. 803 CollectorState state_; 804 #endif 805 806 bool was_marked_incrementally_; 807 808 bool evacuation_; 809 810 // True if we are collecting slots to perform evacuation from evacuation 811 // candidates. 812 bool compacting_; 813 814 bool black_allocation_; 815 816 bool have_code_to_deoptimize_; 817 818 MarkingDeque marking_deque_; 819 820 CodeFlusher* code_flusher_; 821 822 // Candidates for pages that should be evacuated. 823 List<Page*> evacuation_candidates_; 824 // Pages that are actually processed during evacuation. 825 List<Page*> old_space_evacuation_pages_; 826 List<Page*> new_space_evacuation_pages_; 827 828 Sweeper sweeper_; 829 830 friend class Heap; 831 friend class StoreBuffer; 832 }; 833 834 835 class EvacuationScope BASE_EMBEDDED { 836 public: EvacuationScope(MarkCompactCollector * collector)837 explicit EvacuationScope(MarkCompactCollector* collector) 838 : collector_(collector) { 839 collector_->set_evacuation(true); 840 } 841 ~EvacuationScope()842 ~EvacuationScope() { collector_->set_evacuation(false); } 843 844 private: 845 MarkCompactCollector* collector_; 846 }; 847 848 V8_EXPORT_PRIVATE const char* AllocationSpaceName(AllocationSpace space); 849 } // namespace internal 850 } // namespace v8 851 852 #endif // V8_HEAP_MARK_COMPACT_H_ 853