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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 #include "src/heap/heap.h"
6 
7 #include "src/accessors.h"
8 #include "src/api.h"
9 #include "src/ast/scopeinfo.h"
10 #include "src/base/bits.h"
11 #include "src/base/once.h"
12 #include "src/base/utils/random-number-generator.h"
13 #include "src/bootstrapper.h"
14 #include "src/codegen.h"
15 #include "src/compilation-cache.h"
16 #include "src/conversions.h"
17 #include "src/debug/debug.h"
18 #include "src/deoptimizer.h"
19 #include "src/global-handles.h"
20 #include "src/heap/array-buffer-tracker.h"
21 #include "src/heap/gc-idle-time-handler.h"
22 #include "src/heap/gc-tracer.h"
23 #include "src/heap/incremental-marking.h"
24 #include "src/heap/mark-compact-inl.h"
25 #include "src/heap/mark-compact.h"
26 #include "src/heap/memory-reducer.h"
27 #include "src/heap/object-stats.h"
28 #include "src/heap/objects-visiting-inl.h"
29 #include "src/heap/objects-visiting.h"
30 #include "src/heap/scavenge-job.h"
31 #include "src/heap/scavenger-inl.h"
32 #include "src/heap/store-buffer.h"
33 #include "src/interpreter/interpreter.h"
34 #include "src/profiler/cpu-profiler.h"
35 #include "src/regexp/jsregexp.h"
36 #include "src/runtime-profiler.h"
37 #include "src/snapshot/natives.h"
38 #include "src/snapshot/serialize.h"
39 #include "src/snapshot/snapshot.h"
40 #include "src/type-feedback-vector.h"
41 #include "src/utils.h"
42 #include "src/v8.h"
43 #include "src/v8threads.h"
44 #include "src/vm-state-inl.h"
45 
46 namespace v8 {
47 namespace internal {
48 
49 
50 struct Heap::StrongRootsList {
51   Object** start;
52   Object** end;
53   StrongRootsList* next;
54 };
55 
56 class IdleScavengeObserver : public InlineAllocationObserver {
57  public:
IdleScavengeObserver(Heap & heap,intptr_t step_size)58   IdleScavengeObserver(Heap& heap, intptr_t step_size)
59       : InlineAllocationObserver(step_size), heap_(heap) {}
60 
Step(int bytes_allocated,Address,size_t)61   void Step(int bytes_allocated, Address, size_t) override {
62     heap_.ScheduleIdleScavengeIfNeeded(bytes_allocated);
63   }
64 
65  private:
66   Heap& heap_;
67 };
68 
69 
Heap()70 Heap::Heap()
71     : amount_of_external_allocated_memory_(0),
72       amount_of_external_allocated_memory_at_last_global_gc_(0),
73       isolate_(NULL),
74       code_range_size_(0),
75       // semispace_size_ should be a power of 2 and old_generation_size_ should
76       // be a multiple of Page::kPageSize.
77       reserved_semispace_size_(8 * (kPointerSize / 4) * MB),
78       max_semi_space_size_(8 * (kPointerSize / 4) * MB),
79       initial_semispace_size_(Page::kPageSize),
80       target_semispace_size_(Page::kPageSize),
81       max_old_generation_size_(700ul * (kPointerSize / 4) * MB),
82       initial_old_generation_size_(max_old_generation_size_ /
83                                    kInitalOldGenerationLimitFactor),
84       old_generation_size_configured_(false),
85       max_executable_size_(256ul * (kPointerSize / 4) * MB),
86       // Variables set based on semispace_size_ and old_generation_size_ in
87       // ConfigureHeap.
88       // Will be 4 * reserved_semispace_size_ to ensure that young
89       // generation can be aligned to its size.
90       maximum_committed_(0),
91       survived_since_last_expansion_(0),
92       survived_last_scavenge_(0),
93       always_allocate_scope_count_(0),
94       contexts_disposed_(0),
95       number_of_disposed_maps_(0),
96       global_ic_age_(0),
97       scan_on_scavenge_pages_(0),
98       new_space_(this),
99       old_space_(NULL),
100       code_space_(NULL),
101       map_space_(NULL),
102       lo_space_(NULL),
103       gc_state_(NOT_IN_GC),
104       gc_post_processing_depth_(0),
105       allocations_count_(0),
106       raw_allocations_hash_(0),
107       ms_count_(0),
108       gc_count_(0),
109       remembered_unmapped_pages_index_(0),
110 #ifdef DEBUG
111       allocation_timeout_(0),
112 #endif  // DEBUG
113       old_generation_allocation_limit_(initial_old_generation_size_),
114       old_gen_exhausted_(false),
115       optimize_for_memory_usage_(false),
116       inline_allocation_disabled_(false),
117       store_buffer_rebuilder_(store_buffer()),
118       total_regexp_code_generated_(0),
119       tracer_(nullptr),
120       high_survival_rate_period_length_(0),
121       promoted_objects_size_(0),
122       promotion_ratio_(0),
123       semi_space_copied_object_size_(0),
124       previous_semi_space_copied_object_size_(0),
125       semi_space_copied_rate_(0),
126       nodes_died_in_new_space_(0),
127       nodes_copied_in_new_space_(0),
128       nodes_promoted_(0),
129       maximum_size_scavenges_(0),
130       max_gc_pause_(0.0),
131       total_gc_time_ms_(0.0),
132       max_alive_after_gc_(0),
133       min_in_mutator_(kMaxInt),
134       marking_time_(0.0),
135       sweeping_time_(0.0),
136       last_idle_notification_time_(0.0),
137       last_gc_time_(0.0),
138       scavenge_collector_(nullptr),
139       mark_compact_collector_(nullptr),
140       store_buffer_(this),
141       incremental_marking_(nullptr),
142       gc_idle_time_handler_(nullptr),
143       memory_reducer_(nullptr),
144       object_stats_(nullptr),
145       scavenge_job_(nullptr),
146       idle_scavenge_observer_(nullptr),
147       full_codegen_bytes_generated_(0),
148       crankshaft_codegen_bytes_generated_(0),
149       new_space_allocation_counter_(0),
150       old_generation_allocation_counter_(0),
151       old_generation_size_at_last_gc_(0),
152       gcs_since_last_deopt_(0),
153       global_pretenuring_feedback_(nullptr),
154       ring_buffer_full_(false),
155       ring_buffer_end_(0),
156       promotion_queue_(this),
157       configured_(false),
158       current_gc_flags_(Heap::kNoGCFlags),
159       current_gc_callback_flags_(GCCallbackFlags::kNoGCCallbackFlags),
160       external_string_table_(this),
161       chunks_queued_for_free_(NULL),
162       concurrent_unmapping_tasks_active_(0),
163       pending_unmapping_tasks_semaphore_(0),
164       gc_callbacks_depth_(0),
165       deserialization_complete_(false),
166       strong_roots_list_(NULL),
167       array_buffer_tracker_(NULL),
168       heap_iterator_depth_(0),
169       force_oom_(false) {
170 // Allow build-time customization of the max semispace size. Building
171 // V8 with snapshots and a non-default max semispace size is much
172 // easier if you can define it as part of the build environment.
173 #if defined(V8_MAX_SEMISPACE_SIZE)
174   max_semi_space_size_ = reserved_semispace_size_ = V8_MAX_SEMISPACE_SIZE;
175 #endif
176 
177   // Ensure old_generation_size_ is a multiple of kPageSize.
178   DCHECK((max_old_generation_size_ & (Page::kPageSize - 1)) == 0);
179 
180   memset(roots_, 0, sizeof(roots_[0]) * kRootListLength);
181   set_native_contexts_list(NULL);
182   set_allocation_sites_list(Smi::FromInt(0));
183   set_encountered_weak_collections(Smi::FromInt(0));
184   set_encountered_weak_cells(Smi::FromInt(0));
185   set_encountered_transition_arrays(Smi::FromInt(0));
186   // Put a dummy entry in the remembered pages so we can find the list the
187   // minidump even if there are no real unmapped pages.
188   RememberUnmappedPage(NULL, false);
189 }
190 
191 
Capacity()192 intptr_t Heap::Capacity() {
193   if (!HasBeenSetUp()) return 0;
194 
195   return new_space_.Capacity() + old_space_->Capacity() +
196          code_space_->Capacity() + map_space_->Capacity();
197 }
198 
199 
CommittedOldGenerationMemory()200 intptr_t Heap::CommittedOldGenerationMemory() {
201   if (!HasBeenSetUp()) return 0;
202 
203   return old_space_->CommittedMemory() + code_space_->CommittedMemory() +
204          map_space_->CommittedMemory() + lo_space_->Size();
205 }
206 
207 
CommittedMemory()208 intptr_t Heap::CommittedMemory() {
209   if (!HasBeenSetUp()) return 0;
210 
211   return new_space_.CommittedMemory() + CommittedOldGenerationMemory();
212 }
213 
214 
CommittedPhysicalMemory()215 size_t Heap::CommittedPhysicalMemory() {
216   if (!HasBeenSetUp()) return 0;
217 
218   return new_space_.CommittedPhysicalMemory() +
219          old_space_->CommittedPhysicalMemory() +
220          code_space_->CommittedPhysicalMemory() +
221          map_space_->CommittedPhysicalMemory() +
222          lo_space_->CommittedPhysicalMemory();
223 }
224 
225 
CommittedMemoryExecutable()226 intptr_t Heap::CommittedMemoryExecutable() {
227   if (!HasBeenSetUp()) return 0;
228 
229   return isolate()->memory_allocator()->SizeExecutable();
230 }
231 
232 
UpdateMaximumCommitted()233 void Heap::UpdateMaximumCommitted() {
234   if (!HasBeenSetUp()) return;
235 
236   intptr_t current_committed_memory = CommittedMemory();
237   if (current_committed_memory > maximum_committed_) {
238     maximum_committed_ = current_committed_memory;
239   }
240 }
241 
242 
Available()243 intptr_t Heap::Available() {
244   if (!HasBeenSetUp()) return 0;
245 
246   intptr_t total = 0;
247   AllSpaces spaces(this);
248   for (Space* space = spaces.next(); space != NULL; space = spaces.next()) {
249     total += space->Available();
250   }
251   return total;
252 }
253 
254 
HasBeenSetUp()255 bool Heap::HasBeenSetUp() {
256   return old_space_ != NULL && code_space_ != NULL && map_space_ != NULL &&
257          lo_space_ != NULL;
258 }
259 
260 
SelectGarbageCollector(AllocationSpace space,const char ** reason)261 GarbageCollector Heap::SelectGarbageCollector(AllocationSpace space,
262                                               const char** reason) {
263   // Is global GC requested?
264   if (space != NEW_SPACE) {
265     isolate_->counters()->gc_compactor_caused_by_request()->Increment();
266     *reason = "GC in old space requested";
267     return MARK_COMPACTOR;
268   }
269 
270   if (FLAG_gc_global || (FLAG_stress_compaction && (gc_count_ & 1) != 0)) {
271     *reason = "GC in old space forced by flags";
272     return MARK_COMPACTOR;
273   }
274 
275   // Is enough data promoted to justify a global GC?
276   if (OldGenerationAllocationLimitReached()) {
277     isolate_->counters()->gc_compactor_caused_by_promoted_data()->Increment();
278     *reason = "promotion limit reached";
279     return MARK_COMPACTOR;
280   }
281 
282   // Have allocation in OLD and LO failed?
283   if (old_gen_exhausted_) {
284     isolate_->counters()
285         ->gc_compactor_caused_by_oldspace_exhaustion()
286         ->Increment();
287     *reason = "old generations exhausted";
288     return MARK_COMPACTOR;
289   }
290 
291   // Is there enough space left in OLD to guarantee that a scavenge can
292   // succeed?
293   //
294   // Note that MemoryAllocator->MaxAvailable() undercounts the memory available
295   // for object promotion. It counts only the bytes that the memory
296   // allocator has not yet allocated from the OS and assigned to any space,
297   // and does not count available bytes already in the old space or code
298   // space.  Undercounting is safe---we may get an unrequested full GC when
299   // a scavenge would have succeeded.
300   if (isolate_->memory_allocator()->MaxAvailable() <= new_space_.Size()) {
301     isolate_->counters()
302         ->gc_compactor_caused_by_oldspace_exhaustion()
303         ->Increment();
304     *reason = "scavenge might not succeed";
305     return MARK_COMPACTOR;
306   }
307 
308   // Default
309   *reason = NULL;
310   return SCAVENGER;
311 }
312 
313 
314 // TODO(1238405): Combine the infrastructure for --heap-stats and
315 // --log-gc to avoid the complicated preprocessor and flag testing.
ReportStatisticsBeforeGC()316 void Heap::ReportStatisticsBeforeGC() {
317 // Heap::ReportHeapStatistics will also log NewSpace statistics when
318 // compiled --log-gc is set.  The following logic is used to avoid
319 // double logging.
320 #ifdef DEBUG
321   if (FLAG_heap_stats || FLAG_log_gc) new_space_.CollectStatistics();
322   if (FLAG_heap_stats) {
323     ReportHeapStatistics("Before GC");
324   } else if (FLAG_log_gc) {
325     new_space_.ReportStatistics();
326   }
327   if (FLAG_heap_stats || FLAG_log_gc) new_space_.ClearHistograms();
328 #else
329   if (FLAG_log_gc) {
330     new_space_.CollectStatistics();
331     new_space_.ReportStatistics();
332     new_space_.ClearHistograms();
333   }
334 #endif  // DEBUG
335 }
336 
337 
PrintShortHeapStatistics()338 void Heap::PrintShortHeapStatistics() {
339   if (!FLAG_trace_gc_verbose) return;
340   PrintIsolate(isolate_, "Memory allocator,   used: %6" V8_PTR_PREFIX
341                          "d KB"
342                          ", available: %6" V8_PTR_PREFIX "d KB\n",
343                isolate_->memory_allocator()->Size() / KB,
344                isolate_->memory_allocator()->Available() / KB);
345   PrintIsolate(isolate_, "New space,          used: %6" V8_PTR_PREFIX
346                          "d KB"
347                          ", available: %6" V8_PTR_PREFIX
348                          "d KB"
349                          ", committed: %6" V8_PTR_PREFIX "d KB\n",
350                new_space_.Size() / KB, new_space_.Available() / KB,
351                new_space_.CommittedMemory() / KB);
352   PrintIsolate(isolate_, "Old space,          used: %6" V8_PTR_PREFIX
353                          "d KB"
354                          ", available: %6" V8_PTR_PREFIX
355                          "d KB"
356                          ", committed: %6" V8_PTR_PREFIX "d KB\n",
357                old_space_->SizeOfObjects() / KB, old_space_->Available() / KB,
358                old_space_->CommittedMemory() / KB);
359   PrintIsolate(isolate_, "Code space,         used: %6" V8_PTR_PREFIX
360                          "d KB"
361                          ", available: %6" V8_PTR_PREFIX
362                          "d KB"
363                          ", committed: %6" V8_PTR_PREFIX "d KB\n",
364                code_space_->SizeOfObjects() / KB, code_space_->Available() / KB,
365                code_space_->CommittedMemory() / KB);
366   PrintIsolate(isolate_, "Map space,          used: %6" V8_PTR_PREFIX
367                          "d KB"
368                          ", available: %6" V8_PTR_PREFIX
369                          "d KB"
370                          ", committed: %6" V8_PTR_PREFIX "d KB\n",
371                map_space_->SizeOfObjects() / KB, map_space_->Available() / KB,
372                map_space_->CommittedMemory() / KB);
373   PrintIsolate(isolate_, "Large object space, used: %6" V8_PTR_PREFIX
374                          "d KB"
375                          ", available: %6" V8_PTR_PREFIX
376                          "d KB"
377                          ", committed: %6" V8_PTR_PREFIX "d KB\n",
378                lo_space_->SizeOfObjects() / KB, lo_space_->Available() / KB,
379                lo_space_->CommittedMemory() / KB);
380   PrintIsolate(isolate_, "All spaces,         used: %6" V8_PTR_PREFIX
381                          "d KB"
382                          ", available: %6" V8_PTR_PREFIX
383                          "d KB"
384                          ", committed: %6" V8_PTR_PREFIX "d KB\n",
385                this->SizeOfObjects() / KB, this->Available() / KB,
386                this->CommittedMemory() / KB);
387   PrintIsolate(
388       isolate_, "External memory reported: %6" V8_PTR_PREFIX "d KB\n",
389       static_cast<intptr_t>(amount_of_external_allocated_memory_ / KB));
390   PrintIsolate(isolate_, "Total time spent in GC  : %.1f ms\n",
391                total_gc_time_ms_);
392 }
393 
394 
395 // TODO(1238405): Combine the infrastructure for --heap-stats and
396 // --log-gc to avoid the complicated preprocessor and flag testing.
ReportStatisticsAfterGC()397 void Heap::ReportStatisticsAfterGC() {
398 // Similar to the before GC, we use some complicated logic to ensure that
399 // NewSpace statistics are logged exactly once when --log-gc is turned on.
400 #if defined(DEBUG)
401   if (FLAG_heap_stats) {
402     new_space_.CollectStatistics();
403     ReportHeapStatistics("After GC");
404   } else if (FLAG_log_gc) {
405     new_space_.ReportStatistics();
406   }
407 #else
408   if (FLAG_log_gc) new_space_.ReportStatistics();
409 #endif  // DEBUG
410   for (int i = 0; i < static_cast<int>(v8::Isolate::kUseCounterFeatureCount);
411        ++i) {
412     int count = deferred_counters_[i];
413     deferred_counters_[i] = 0;
414     while (count > 0) {
415       count--;
416       isolate()->CountUsage(static_cast<v8::Isolate::UseCounterFeature>(i));
417     }
418   }
419 }
420 
421 
IncrementDeferredCount(v8::Isolate::UseCounterFeature feature)422 void Heap::IncrementDeferredCount(v8::Isolate::UseCounterFeature feature) {
423   deferred_counters_[feature]++;
424 }
425 
426 
GarbageCollectionPrologue()427 void Heap::GarbageCollectionPrologue() {
428   {
429     AllowHeapAllocation for_the_first_part_of_prologue;
430     gc_count_++;
431 
432 #ifdef VERIFY_HEAP
433     if (FLAG_verify_heap) {
434       Verify();
435     }
436 #endif
437   }
438 
439   // Reset GC statistics.
440   promoted_objects_size_ = 0;
441   previous_semi_space_copied_object_size_ = semi_space_copied_object_size_;
442   semi_space_copied_object_size_ = 0;
443   nodes_died_in_new_space_ = 0;
444   nodes_copied_in_new_space_ = 0;
445   nodes_promoted_ = 0;
446 
447   UpdateMaximumCommitted();
448 
449 #ifdef DEBUG
450   DCHECK(!AllowHeapAllocation::IsAllowed() && gc_state_ == NOT_IN_GC);
451 
452   if (FLAG_gc_verbose) Print();
453 
454   ReportStatisticsBeforeGC();
455 #endif  // DEBUG
456 
457   store_buffer()->GCPrologue();
458 
459   if (isolate()->concurrent_osr_enabled()) {
460     isolate()->optimizing_compile_dispatcher()->AgeBufferedOsrJobs();
461   }
462 
463   if (new_space_.IsAtMaximumCapacity()) {
464     maximum_size_scavenges_++;
465   } else {
466     maximum_size_scavenges_ = 0;
467   }
468   CheckNewSpaceExpansionCriteria();
469   UpdateNewSpaceAllocationCounter();
470 }
471 
472 
SizeOfObjects()473 intptr_t Heap::SizeOfObjects() {
474   intptr_t total = 0;
475   AllSpaces spaces(this);
476   for (Space* space = spaces.next(); space != NULL; space = spaces.next()) {
477     total += space->SizeOfObjects();
478   }
479   return total;
480 }
481 
482 
GetSpaceName(int idx)483 const char* Heap::GetSpaceName(int idx) {
484   switch (idx) {
485     case NEW_SPACE:
486       return "new_space";
487     case OLD_SPACE:
488       return "old_space";
489     case MAP_SPACE:
490       return "map_space";
491     case CODE_SPACE:
492       return "code_space";
493     case LO_SPACE:
494       return "large_object_space";
495     default:
496       UNREACHABLE();
497   }
498   return nullptr;
499 }
500 
501 
RepairFreeListsAfterDeserialization()502 void Heap::RepairFreeListsAfterDeserialization() {
503   PagedSpaces spaces(this);
504   for (PagedSpace* space = spaces.next(); space != NULL;
505        space = spaces.next()) {
506     space->RepairFreeListsAfterDeserialization();
507   }
508 }
509 
510 
MergeAllocationSitePretenuringFeedback(const HashMap & local_pretenuring_feedback)511 void Heap::MergeAllocationSitePretenuringFeedback(
512     const HashMap& local_pretenuring_feedback) {
513   AllocationSite* site = nullptr;
514   for (HashMap::Entry* local_entry = local_pretenuring_feedback.Start();
515        local_entry != nullptr;
516        local_entry = local_pretenuring_feedback.Next(local_entry)) {
517     site = reinterpret_cast<AllocationSite*>(local_entry->key);
518     MapWord map_word = site->map_word();
519     if (map_word.IsForwardingAddress()) {
520       site = AllocationSite::cast(map_word.ToForwardingAddress());
521     }
522     DCHECK(site->IsAllocationSite());
523     int value =
524         static_cast<int>(reinterpret_cast<intptr_t>(local_entry->value));
525     DCHECK_GT(value, 0);
526 
527     {
528       // TODO(mlippautz): For parallel processing we need synchronization here.
529       if (site->IncrementMementoFoundCount(value)) {
530         global_pretenuring_feedback_->LookupOrInsert(
531             site, static_cast<uint32_t>(bit_cast<uintptr_t>(site)));
532       }
533     }
534   }
535 }
536 
537 
538 class Heap::PretenuringScope {
539  public:
PretenuringScope(Heap * heap)540   explicit PretenuringScope(Heap* heap) : heap_(heap) {
541     heap_->global_pretenuring_feedback_ =
542         new HashMap(HashMap::PointersMatch, kInitialFeedbackCapacity);
543   }
544 
~PretenuringScope()545   ~PretenuringScope() {
546     delete heap_->global_pretenuring_feedback_;
547     heap_->global_pretenuring_feedback_ = nullptr;
548   }
549 
550  private:
551   Heap* heap_;
552 };
553 
554 
ProcessPretenuringFeedback()555 void Heap::ProcessPretenuringFeedback() {
556   bool trigger_deoptimization = false;
557   if (FLAG_allocation_site_pretenuring) {
558     int tenure_decisions = 0;
559     int dont_tenure_decisions = 0;
560     int allocation_mementos_found = 0;
561     int allocation_sites = 0;
562     int active_allocation_sites = 0;
563 
564     AllocationSite* site = nullptr;
565 
566     // Step 1: Digest feedback for recorded allocation sites.
567     bool maximum_size_scavenge = MaximumSizeScavenge();
568     for (HashMap::Entry* e = global_pretenuring_feedback_->Start();
569          e != nullptr; e = global_pretenuring_feedback_->Next(e)) {
570       site = reinterpret_cast<AllocationSite*>(e->key);
571       int found_count = site->memento_found_count();
572       // The fact that we have an entry in the storage means that we've found
573       // the site at least once.
574       DCHECK_GT(found_count, 0);
575       DCHECK(site->IsAllocationSite());
576       allocation_sites++;
577       active_allocation_sites++;
578       allocation_mementos_found += found_count;
579       if (site->DigestPretenuringFeedback(maximum_size_scavenge)) {
580         trigger_deoptimization = true;
581       }
582       if (site->GetPretenureMode() == TENURED) {
583         tenure_decisions++;
584       } else {
585         dont_tenure_decisions++;
586       }
587     }
588 
589     // Step 2: Deopt maybe tenured allocation sites if necessary.
590     bool deopt_maybe_tenured = DeoptMaybeTenuredAllocationSites();
591     if (deopt_maybe_tenured) {
592       Object* list_element = allocation_sites_list();
593       while (list_element->IsAllocationSite()) {
594         site = AllocationSite::cast(list_element);
595         DCHECK(site->IsAllocationSite());
596         allocation_sites++;
597         if (site->IsMaybeTenure()) {
598           site->set_deopt_dependent_code(true);
599           trigger_deoptimization = true;
600         }
601         list_element = site->weak_next();
602       }
603     }
604 
605     if (trigger_deoptimization) {
606       isolate_->stack_guard()->RequestDeoptMarkedAllocationSites();
607     }
608 
609     if (FLAG_trace_pretenuring_statistics &&
610         (allocation_mementos_found > 0 || tenure_decisions > 0 ||
611          dont_tenure_decisions > 0)) {
612       PrintIsolate(isolate(),
613                    "pretenuring: deopt_maybe_tenured=%d visited_sites=%d "
614                    "active_sites=%d "
615                    "mementos=%d tenured=%d not_tenured=%d\n",
616                    deopt_maybe_tenured ? 1 : 0, allocation_sites,
617                    active_allocation_sites, allocation_mementos_found,
618                    tenure_decisions, dont_tenure_decisions);
619     }
620   }
621 }
622 
623 
DeoptMarkedAllocationSites()624 void Heap::DeoptMarkedAllocationSites() {
625   // TODO(hpayer): If iterating over the allocation sites list becomes a
626   // performance issue, use a cache data structure in heap instead.
627   Object* list_element = allocation_sites_list();
628   while (list_element->IsAllocationSite()) {
629     AllocationSite* site = AllocationSite::cast(list_element);
630     if (site->deopt_dependent_code()) {
631       site->dependent_code()->MarkCodeForDeoptimization(
632           isolate_, DependentCode::kAllocationSiteTenuringChangedGroup);
633       site->set_deopt_dependent_code(false);
634     }
635     list_element = site->weak_next();
636   }
637   Deoptimizer::DeoptimizeMarkedCode(isolate_);
638 }
639 
640 
GarbageCollectionEpilogue()641 void Heap::GarbageCollectionEpilogue() {
642   store_buffer()->GCEpilogue();
643 
644   // In release mode, we only zap the from space under heap verification.
645   if (Heap::ShouldZapGarbage()) {
646     ZapFromSpace();
647   }
648 
649 #ifdef VERIFY_HEAP
650   if (FLAG_verify_heap) {
651     Verify();
652   }
653 #endif
654 
655   AllowHeapAllocation for_the_rest_of_the_epilogue;
656 
657 #ifdef DEBUG
658   if (FLAG_print_global_handles) isolate_->global_handles()->Print();
659   if (FLAG_print_handles) PrintHandles();
660   if (FLAG_gc_verbose) Print();
661   if (FLAG_code_stats) ReportCodeStatistics("After GC");
662   if (FLAG_check_handle_count) CheckHandleCount();
663 #endif
664   if (FLAG_deopt_every_n_garbage_collections > 0) {
665     // TODO(jkummerow/ulan/jarin): This is not safe! We can't assume that
666     // the topmost optimized frame can be deoptimized safely, because it
667     // might not have a lazy bailout point right after its current PC.
668     if (++gcs_since_last_deopt_ == FLAG_deopt_every_n_garbage_collections) {
669       Deoptimizer::DeoptimizeAll(isolate());
670       gcs_since_last_deopt_ = 0;
671     }
672   }
673 
674   UpdateMaximumCommitted();
675 
676   isolate_->counters()->alive_after_last_gc()->Set(
677       static_cast<int>(SizeOfObjects()));
678 
679   isolate_->counters()->string_table_capacity()->Set(
680       string_table()->Capacity());
681   isolate_->counters()->number_of_symbols()->Set(
682       string_table()->NumberOfElements());
683 
684   if (full_codegen_bytes_generated_ + crankshaft_codegen_bytes_generated_ > 0) {
685     isolate_->counters()->codegen_fraction_crankshaft()->AddSample(
686         static_cast<int>((crankshaft_codegen_bytes_generated_ * 100.0) /
687                          (crankshaft_codegen_bytes_generated_ +
688                           full_codegen_bytes_generated_)));
689   }
690 
691   if (CommittedMemory() > 0) {
692     isolate_->counters()->external_fragmentation_total()->AddSample(
693         static_cast<int>(100 - (SizeOfObjects() * 100.0) / CommittedMemory()));
694 
695     isolate_->counters()->heap_fraction_new_space()->AddSample(static_cast<int>(
696         (new_space()->CommittedMemory() * 100.0) / CommittedMemory()));
697     isolate_->counters()->heap_fraction_old_space()->AddSample(static_cast<int>(
698         (old_space()->CommittedMemory() * 100.0) / CommittedMemory()));
699     isolate_->counters()->heap_fraction_code_space()->AddSample(
700         static_cast<int>((code_space()->CommittedMemory() * 100.0) /
701                          CommittedMemory()));
702     isolate_->counters()->heap_fraction_map_space()->AddSample(static_cast<int>(
703         (map_space()->CommittedMemory() * 100.0) / CommittedMemory()));
704     isolate_->counters()->heap_fraction_lo_space()->AddSample(static_cast<int>(
705         (lo_space()->CommittedMemory() * 100.0) / CommittedMemory()));
706 
707     isolate_->counters()->heap_sample_total_committed()->AddSample(
708         static_cast<int>(CommittedMemory() / KB));
709     isolate_->counters()->heap_sample_total_used()->AddSample(
710         static_cast<int>(SizeOfObjects() / KB));
711     isolate_->counters()->heap_sample_map_space_committed()->AddSample(
712         static_cast<int>(map_space()->CommittedMemory() / KB));
713     isolate_->counters()->heap_sample_code_space_committed()->AddSample(
714         static_cast<int>(code_space()->CommittedMemory() / KB));
715 
716     isolate_->counters()->heap_sample_maximum_committed()->AddSample(
717         static_cast<int>(MaximumCommittedMemory() / KB));
718   }
719 
720 #define UPDATE_COUNTERS_FOR_SPACE(space)                \
721   isolate_->counters()->space##_bytes_available()->Set( \
722       static_cast<int>(space()->Available()));          \
723   isolate_->counters()->space##_bytes_committed()->Set( \
724       static_cast<int>(space()->CommittedMemory()));    \
725   isolate_->counters()->space##_bytes_used()->Set(      \
726       static_cast<int>(space()->SizeOfObjects()));
727 #define UPDATE_FRAGMENTATION_FOR_SPACE(space)                          \
728   if (space()->CommittedMemory() > 0) {                                \
729     isolate_->counters()->external_fragmentation_##space()->AddSample( \
730         static_cast<int>(100 -                                         \
731                          (space()->SizeOfObjects() * 100.0) /          \
732                              space()->CommittedMemory()));             \
733   }
734 #define UPDATE_COUNTERS_AND_FRAGMENTATION_FOR_SPACE(space) \
735   UPDATE_COUNTERS_FOR_SPACE(space)                         \
736   UPDATE_FRAGMENTATION_FOR_SPACE(space)
737 
738   UPDATE_COUNTERS_FOR_SPACE(new_space)
739   UPDATE_COUNTERS_AND_FRAGMENTATION_FOR_SPACE(old_space)
740   UPDATE_COUNTERS_AND_FRAGMENTATION_FOR_SPACE(code_space)
741   UPDATE_COUNTERS_AND_FRAGMENTATION_FOR_SPACE(map_space)
742   UPDATE_COUNTERS_AND_FRAGMENTATION_FOR_SPACE(lo_space)
743 #undef UPDATE_COUNTERS_FOR_SPACE
744 #undef UPDATE_FRAGMENTATION_FOR_SPACE
745 #undef UPDATE_COUNTERS_AND_FRAGMENTATION_FOR_SPACE
746 
747 #ifdef DEBUG
748   ReportStatisticsAfterGC();
749 #endif  // DEBUG
750 
751   // Remember the last top pointer so that we can later find out
752   // whether we allocated in new space since the last GC.
753   new_space_top_after_last_gc_ = new_space()->top();
754   last_gc_time_ = MonotonicallyIncreasingTimeInMs();
755 
756   ReduceNewSpaceSize();
757 }
758 
759 
PreprocessStackTraces()760 void Heap::PreprocessStackTraces() {
761   WeakFixedArray::Iterator iterator(weak_stack_trace_list());
762   FixedArray* elements;
763   while ((elements = iterator.Next<FixedArray>())) {
764     for (int j = 1; j < elements->length(); j += 4) {
765       Object* maybe_code = elements->get(j + 2);
766       // If GC happens while adding a stack trace to the weak fixed array,
767       // which has been copied into a larger backing store, we may run into
768       // a stack trace that has already been preprocessed. Guard against this.
769       if (!maybe_code->IsCode()) break;
770       Code* code = Code::cast(maybe_code);
771       int offset = Smi::cast(elements->get(j + 3))->value();
772       Address pc = code->address() + offset;
773       int pos = code->SourcePosition(pc);
774       elements->set(j + 2, Smi::FromInt(pos));
775     }
776   }
777   // We must not compact the weak fixed list here, as we may be in the middle
778   // of writing to it, when the GC triggered. Instead, we reset the root value.
779   set_weak_stack_trace_list(Smi::FromInt(0));
780 }
781 
782 
783 class GCCallbacksScope {
784  public:
GCCallbacksScope(Heap * heap)785   explicit GCCallbacksScope(Heap* heap) : heap_(heap) {
786     heap_->gc_callbacks_depth_++;
787   }
~GCCallbacksScope()788   ~GCCallbacksScope() { heap_->gc_callbacks_depth_--; }
789 
CheckReenter()790   bool CheckReenter() { return heap_->gc_callbacks_depth_ == 1; }
791 
792  private:
793   Heap* heap_;
794 };
795 
796 
HandleGCRequest()797 void Heap::HandleGCRequest() {
798   if (incremental_marking()->request_type() ==
799       IncrementalMarking::COMPLETE_MARKING) {
800     CollectAllGarbage(current_gc_flags_, "GC interrupt",
801                       current_gc_callback_flags_);
802   } else if (incremental_marking()->IsMarking() &&
803              !incremental_marking()->finalize_marking_completed()) {
804     FinalizeIncrementalMarking("GC interrupt: finalize incremental marking");
805   }
806 }
807 
808 
ScheduleIdleScavengeIfNeeded(int bytes_allocated)809 void Heap::ScheduleIdleScavengeIfNeeded(int bytes_allocated) {
810   scavenge_job_->ScheduleIdleTaskIfNeeded(this, bytes_allocated);
811 }
812 
813 
FinalizeIncrementalMarking(const char * gc_reason)814 void Heap::FinalizeIncrementalMarking(const char* gc_reason) {
815   if (FLAG_trace_incremental_marking) {
816     PrintF("[IncrementalMarking] (%s).\n", gc_reason);
817   }
818 
819   GCTracer::Scope gc_scope(tracer(), GCTracer::Scope::MC_INCREMENTAL_FINALIZE);
820   HistogramTimerScope incremental_marking_scope(
821       isolate()->counters()->gc_incremental_marking_finalize());
822 
823   {
824     GCCallbacksScope scope(this);
825     if (scope.CheckReenter()) {
826       AllowHeapAllocation allow_allocation;
827       GCTracer::Scope scope(tracer(), GCTracer::Scope::EXTERNAL);
828       VMState<EXTERNAL> state(isolate_);
829       HandleScope handle_scope(isolate_);
830       CallGCPrologueCallbacks(kGCTypeIncrementalMarking, kNoGCCallbackFlags);
831     }
832   }
833   incremental_marking()->FinalizeIncrementally();
834   {
835     GCCallbacksScope scope(this);
836     if (scope.CheckReenter()) {
837       AllowHeapAllocation allow_allocation;
838       GCTracer::Scope scope(tracer(), GCTracer::Scope::EXTERNAL);
839       VMState<EXTERNAL> state(isolate_);
840       HandleScope handle_scope(isolate_);
841       CallGCEpilogueCallbacks(kGCTypeIncrementalMarking, kNoGCCallbackFlags);
842     }
843   }
844 }
845 
846 
GCTypeTimer(GarbageCollector collector)847 HistogramTimer* Heap::GCTypeTimer(GarbageCollector collector) {
848   if (collector == SCAVENGER) {
849     return isolate_->counters()->gc_scavenger();
850   } else {
851     if (!incremental_marking()->IsStopped()) {
852       if (ShouldReduceMemory()) {
853         return isolate_->counters()->gc_finalize_reduce_memory();
854       } else {
855         return isolate_->counters()->gc_finalize();
856       }
857     } else {
858       return isolate_->counters()->gc_compactor();
859     }
860   }
861 }
862 
863 
CollectAllGarbage(int flags,const char * gc_reason,const v8::GCCallbackFlags gc_callback_flags)864 void Heap::CollectAllGarbage(int flags, const char* gc_reason,
865                              const v8::GCCallbackFlags gc_callback_flags) {
866   // Since we are ignoring the return value, the exact choice of space does
867   // not matter, so long as we do not specify NEW_SPACE, which would not
868   // cause a full GC.
869   set_current_gc_flags(flags);
870   CollectGarbage(OLD_SPACE, gc_reason, gc_callback_flags);
871   set_current_gc_flags(kNoGCFlags);
872 }
873 
874 
CollectAllAvailableGarbage(const char * gc_reason)875 void Heap::CollectAllAvailableGarbage(const char* gc_reason) {
876   // Since we are ignoring the return value, the exact choice of space does
877   // not matter, so long as we do not specify NEW_SPACE, which would not
878   // cause a full GC.
879   // Major GC would invoke weak handle callbacks on weakly reachable
880   // handles, but won't collect weakly reachable objects until next
881   // major GC.  Therefore if we collect aggressively and weak handle callback
882   // has been invoked, we rerun major GC to release objects which become
883   // garbage.
884   // Note: as weak callbacks can execute arbitrary code, we cannot
885   // hope that eventually there will be no weak callbacks invocations.
886   // Therefore stop recollecting after several attempts.
887   if (isolate()->concurrent_recompilation_enabled()) {
888     // The optimizing compiler may be unnecessarily holding on to memory.
889     DisallowHeapAllocation no_recursive_gc;
890     isolate()->optimizing_compile_dispatcher()->Flush();
891   }
892   isolate()->ClearSerializerData();
893   set_current_gc_flags(kMakeHeapIterableMask | kReduceMemoryFootprintMask);
894   isolate_->compilation_cache()->Clear();
895   const int kMaxNumberOfAttempts = 7;
896   const int kMinNumberOfAttempts = 2;
897   for (int attempt = 0; attempt < kMaxNumberOfAttempts; attempt++) {
898     if (!CollectGarbage(MARK_COMPACTOR, gc_reason, NULL,
899                         v8::kGCCallbackFlagForced) &&
900         attempt + 1 >= kMinNumberOfAttempts) {
901       break;
902     }
903   }
904   set_current_gc_flags(kNoGCFlags);
905   new_space_.Shrink();
906   UncommitFromSpace();
907 }
908 
909 
ReportExternalMemoryPressure(const char * gc_reason)910 void Heap::ReportExternalMemoryPressure(const char* gc_reason) {
911   if (incremental_marking()->IsStopped()) {
912     if (incremental_marking()->CanBeActivated()) {
913       StartIncrementalMarking(
914           i::Heap::kNoGCFlags,
915           kGCCallbackFlagSynchronousPhantomCallbackProcessing, gc_reason);
916     } else {
917       CollectAllGarbage(i::Heap::kNoGCFlags, gc_reason,
918                         kGCCallbackFlagSynchronousPhantomCallbackProcessing);
919     }
920   } else {
921     // Incremental marking is turned on an has already been started.
922 
923     // TODO(mlippautz): Compute the time slice for incremental marking based on
924     // memory pressure.
925     double deadline = MonotonicallyIncreasingTimeInMs() +
926                       FLAG_external_allocation_limit_incremental_time;
927     incremental_marking()->AdvanceIncrementalMarking(
928         0, deadline,
929         IncrementalMarking::StepActions(IncrementalMarking::GC_VIA_STACK_GUARD,
930                                         IncrementalMarking::FORCE_MARKING,
931                                         IncrementalMarking::FORCE_COMPLETION));
932   }
933 }
934 
935 
EnsureFillerObjectAtTop()936 void Heap::EnsureFillerObjectAtTop() {
937   // There may be an allocation memento behind every object in new space.
938   // If we evacuate a not full new space or if we are on the last page of
939   // the new space, then there may be uninitialized memory behind the top
940   // pointer of the new space page. We store a filler object there to
941   // identify the unused space.
942   Address from_top = new_space_.top();
943   // Check that from_top is inside its page (i.e., not at the end).
944   Address space_end = new_space_.ToSpaceEnd();
945   if (from_top < space_end) {
946     Page* page = Page::FromAddress(from_top);
947     if (page->Contains(from_top)) {
948       int remaining_in_page = static_cast<int>(page->area_end() - from_top);
949       CreateFillerObjectAt(from_top, remaining_in_page);
950     }
951   }
952 }
953 
954 
CollectGarbage(GarbageCollector collector,const char * gc_reason,const char * collector_reason,const v8::GCCallbackFlags gc_callback_flags)955 bool Heap::CollectGarbage(GarbageCollector collector, const char* gc_reason,
956                           const char* collector_reason,
957                           const v8::GCCallbackFlags gc_callback_flags) {
958   // The VM is in the GC state until exiting this function.
959   VMState<GC> state(isolate_);
960 
961 #ifdef DEBUG
962   // Reset the allocation timeout to the GC interval, but make sure to
963   // allow at least a few allocations after a collection. The reason
964   // for this is that we have a lot of allocation sequences and we
965   // assume that a garbage collection will allow the subsequent
966   // allocation attempts to go through.
967   allocation_timeout_ = Max(6, FLAG_gc_interval);
968 #endif
969 
970   EnsureFillerObjectAtTop();
971 
972   if (collector == SCAVENGER && !incremental_marking()->IsStopped()) {
973     if (FLAG_trace_incremental_marking) {
974       PrintF("[IncrementalMarking] Scavenge during marking.\n");
975     }
976   }
977 
978   if (collector == MARK_COMPACTOR && !ShouldFinalizeIncrementalMarking() &&
979       !ShouldAbortIncrementalMarking() && !incremental_marking()->IsStopped() &&
980       !incremental_marking()->should_hurry() && FLAG_incremental_marking &&
981       OldGenerationAllocationLimitReached()) {
982     // Make progress in incremental marking.
983     const intptr_t kStepSizeWhenDelayedByScavenge = 1 * MB;
984     incremental_marking()->Step(kStepSizeWhenDelayedByScavenge,
985                                 IncrementalMarking::NO_GC_VIA_STACK_GUARD);
986     if (!incremental_marking()->IsComplete() &&
987         !mark_compact_collector()->marking_deque_.IsEmpty() &&
988         !FLAG_gc_global) {
989       if (FLAG_trace_incremental_marking) {
990         PrintF("[IncrementalMarking] Delaying MarkSweep.\n");
991       }
992       collector = SCAVENGER;
993       collector_reason = "incremental marking delaying mark-sweep";
994     }
995   }
996 
997   bool next_gc_likely_to_collect_more = false;
998   intptr_t committed_memory_before = 0;
999 
1000   if (collector == MARK_COMPACTOR) {
1001     committed_memory_before = CommittedOldGenerationMemory();
1002   }
1003 
1004   {
1005     tracer()->Start(collector, gc_reason, collector_reason);
1006     DCHECK(AllowHeapAllocation::IsAllowed());
1007     DisallowHeapAllocation no_allocation_during_gc;
1008     GarbageCollectionPrologue();
1009 
1010     {
1011       HistogramTimerScope histogram_timer_scope(GCTypeTimer(collector));
1012 
1013       next_gc_likely_to_collect_more =
1014           PerformGarbageCollection(collector, gc_callback_flags);
1015     }
1016 
1017     GarbageCollectionEpilogue();
1018     if (collector == MARK_COMPACTOR && FLAG_track_detached_contexts) {
1019       isolate()->CheckDetachedContextsAfterGC();
1020     }
1021 
1022     if (collector == MARK_COMPACTOR) {
1023       intptr_t committed_memory_after = CommittedOldGenerationMemory();
1024       intptr_t used_memory_after = PromotedSpaceSizeOfObjects();
1025       MemoryReducer::Event event;
1026       event.type = MemoryReducer::kMarkCompact;
1027       event.time_ms = MonotonicallyIncreasingTimeInMs();
1028       // Trigger one more GC if
1029       // - this GC decreased committed memory,
1030       // - there is high fragmentation,
1031       // - there are live detached contexts.
1032       event.next_gc_likely_to_collect_more =
1033           (committed_memory_before - committed_memory_after) > MB ||
1034           HasHighFragmentation(used_memory_after, committed_memory_after) ||
1035           (detached_contexts()->length() > 0);
1036       if (deserialization_complete_) {
1037         memory_reducer_->NotifyMarkCompact(event);
1038       }
1039     }
1040 
1041     tracer()->Stop(collector);
1042   }
1043 
1044   if (collector == MARK_COMPACTOR &&
1045       (gc_callback_flags & kGCCallbackFlagForced) != 0) {
1046     isolate()->CountUsage(v8::Isolate::kForcedGC);
1047   }
1048 
1049   // Start incremental marking for the next cycle. The heap snapshot
1050   // generator needs incremental marking to stay off after it aborted.
1051   if (!ShouldAbortIncrementalMarking() && incremental_marking()->IsStopped() &&
1052       incremental_marking()->ShouldActivateEvenWithoutIdleNotification()) {
1053     StartIncrementalMarking(kNoGCFlags, kNoGCCallbackFlags, "GC epilogue");
1054   }
1055 
1056   return next_gc_likely_to_collect_more;
1057 }
1058 
1059 
NotifyContextDisposed(bool dependant_context)1060 int Heap::NotifyContextDisposed(bool dependant_context) {
1061   if (!dependant_context) {
1062     tracer()->ResetSurvivalEvents();
1063     old_generation_size_configured_ = false;
1064     MemoryReducer::Event event;
1065     event.type = MemoryReducer::kContextDisposed;
1066     event.time_ms = MonotonicallyIncreasingTimeInMs();
1067     memory_reducer_->NotifyContextDisposed(event);
1068   }
1069   if (isolate()->concurrent_recompilation_enabled()) {
1070     // Flush the queued recompilation tasks.
1071     isolate()->optimizing_compile_dispatcher()->Flush();
1072   }
1073   AgeInlineCaches();
1074   number_of_disposed_maps_ = retained_maps()->Length();
1075   tracer()->AddContextDisposalTime(MonotonicallyIncreasingTimeInMs());
1076   return ++contexts_disposed_;
1077 }
1078 
1079 
StartIncrementalMarking(int gc_flags,const GCCallbackFlags gc_callback_flags,const char * reason)1080 void Heap::StartIncrementalMarking(int gc_flags,
1081                                    const GCCallbackFlags gc_callback_flags,
1082                                    const char* reason) {
1083   DCHECK(incremental_marking()->IsStopped());
1084   set_current_gc_flags(gc_flags);
1085   current_gc_callback_flags_ = gc_callback_flags;
1086   incremental_marking()->Start(reason);
1087 }
1088 
1089 
StartIdleIncrementalMarking()1090 void Heap::StartIdleIncrementalMarking() {
1091   gc_idle_time_handler_->ResetNoProgressCounter();
1092   StartIncrementalMarking(kReduceMemoryFootprintMask, kNoGCCallbackFlags,
1093                           "idle");
1094 }
1095 
1096 
MoveElements(FixedArray * array,int dst_index,int src_index,int len)1097 void Heap::MoveElements(FixedArray* array, int dst_index, int src_index,
1098                         int len) {
1099   if (len == 0) return;
1100 
1101   DCHECK(array->map() != fixed_cow_array_map());
1102   Object** dst_objects = array->data_start() + dst_index;
1103   MemMove(dst_objects, array->data_start() + src_index, len * kPointerSize);
1104   if (!InNewSpace(array)) {
1105     for (int i = 0; i < len; i++) {
1106       // TODO(hpayer): check store buffer for entries
1107       if (InNewSpace(dst_objects[i])) {
1108         RecordWrite(array->address(), array->OffsetOfElementAt(dst_index + i));
1109       }
1110     }
1111   }
1112   incremental_marking()->RecordWrites(array);
1113 }
1114 
1115 
1116 #ifdef VERIFY_HEAP
1117 // Helper class for verifying the string table.
1118 class StringTableVerifier : public ObjectVisitor {
1119  public:
VisitPointers(Object ** start,Object ** end)1120   void VisitPointers(Object** start, Object** end) override {
1121     // Visit all HeapObject pointers in [start, end).
1122     for (Object** p = start; p < end; p++) {
1123       if ((*p)->IsHeapObject()) {
1124         // Check that the string is actually internalized.
1125         CHECK((*p)->IsTheHole() || (*p)->IsUndefined() ||
1126               (*p)->IsInternalizedString());
1127       }
1128     }
1129   }
1130 };
1131 
1132 
VerifyStringTable(Heap * heap)1133 static void VerifyStringTable(Heap* heap) {
1134   StringTableVerifier verifier;
1135   heap->string_table()->IterateElements(&verifier);
1136 }
1137 #endif  // VERIFY_HEAP
1138 
1139 
ReserveSpace(Reservation * reservations)1140 bool Heap::ReserveSpace(Reservation* reservations) {
1141   bool gc_performed = true;
1142   int counter = 0;
1143   static const int kThreshold = 20;
1144   while (gc_performed && counter++ < kThreshold) {
1145     gc_performed = false;
1146     for (int space = NEW_SPACE; space < Serializer::kNumberOfSpaces; space++) {
1147       Reservation* reservation = &reservations[space];
1148       DCHECK_LE(1, reservation->length());
1149       if (reservation->at(0).size == 0) continue;
1150       bool perform_gc = false;
1151       if (space == LO_SPACE) {
1152         DCHECK_EQ(1, reservation->length());
1153         perform_gc = !CanExpandOldGeneration(reservation->at(0).size);
1154       } else {
1155         for (auto& chunk : *reservation) {
1156           AllocationResult allocation;
1157           int size = chunk.size;
1158           DCHECK_LE(size, MemoryAllocator::PageAreaSize(
1159                               static_cast<AllocationSpace>(space)));
1160           if (space == NEW_SPACE) {
1161             allocation = new_space()->AllocateRawUnaligned(size);
1162           } else {
1163             allocation = paged_space(space)->AllocateRawUnaligned(size);
1164           }
1165           HeapObject* free_space = nullptr;
1166           if (allocation.To(&free_space)) {
1167             // Mark with a free list node, in case we have a GC before
1168             // deserializing.
1169             Address free_space_address = free_space->address();
1170             CreateFillerObjectAt(free_space_address, size);
1171             DCHECK(space < Serializer::kNumberOfPreallocatedSpaces);
1172             chunk.start = free_space_address;
1173             chunk.end = free_space_address + size;
1174           } else {
1175             perform_gc = true;
1176             break;
1177           }
1178         }
1179       }
1180       if (perform_gc) {
1181         if (space == NEW_SPACE) {
1182           CollectGarbage(NEW_SPACE, "failed to reserve space in the new space");
1183         } else {
1184           if (counter > 1) {
1185             CollectAllGarbage(
1186                 kReduceMemoryFootprintMask | kAbortIncrementalMarkingMask,
1187                 "failed to reserve space in paged or large "
1188                 "object space, trying to reduce memory footprint");
1189           } else {
1190             CollectAllGarbage(
1191                 kAbortIncrementalMarkingMask,
1192                 "failed to reserve space in paged or large object space");
1193           }
1194         }
1195         gc_performed = true;
1196         break;  // Abort for-loop over spaces and retry.
1197       }
1198     }
1199   }
1200 
1201   return !gc_performed;
1202 }
1203 
1204 
EnsureFromSpaceIsCommitted()1205 void Heap::EnsureFromSpaceIsCommitted() {
1206   if (new_space_.CommitFromSpaceIfNeeded()) return;
1207 
1208   // Committing memory to from space failed.
1209   // Memory is exhausted and we will die.
1210   V8::FatalProcessOutOfMemory("Committing semi space failed.");
1211 }
1212 
1213 
ClearNormalizedMapCaches()1214 void Heap::ClearNormalizedMapCaches() {
1215   if (isolate_->bootstrapper()->IsActive() &&
1216       !incremental_marking()->IsMarking()) {
1217     return;
1218   }
1219 
1220   Object* context = native_contexts_list();
1221   while (!context->IsUndefined()) {
1222     // GC can happen when the context is not fully initialized,
1223     // so the cache can be undefined.
1224     Object* cache =
1225         Context::cast(context)->get(Context::NORMALIZED_MAP_CACHE_INDEX);
1226     if (!cache->IsUndefined()) {
1227       NormalizedMapCache::cast(cache)->Clear();
1228     }
1229     context = Context::cast(context)->get(Context::NEXT_CONTEXT_LINK);
1230   }
1231 }
1232 
1233 
UpdateSurvivalStatistics(int start_new_space_size)1234 void Heap::UpdateSurvivalStatistics(int start_new_space_size) {
1235   if (start_new_space_size == 0) return;
1236 
1237   promotion_ratio_ = (static_cast<double>(promoted_objects_size_) /
1238                       static_cast<double>(start_new_space_size) * 100);
1239 
1240   if (previous_semi_space_copied_object_size_ > 0) {
1241     promotion_rate_ =
1242         (static_cast<double>(promoted_objects_size_) /
1243          static_cast<double>(previous_semi_space_copied_object_size_) * 100);
1244   } else {
1245     promotion_rate_ = 0;
1246   }
1247 
1248   semi_space_copied_rate_ =
1249       (static_cast<double>(semi_space_copied_object_size_) /
1250        static_cast<double>(start_new_space_size) * 100);
1251 
1252   double survival_rate = promotion_ratio_ + semi_space_copied_rate_;
1253   tracer()->AddSurvivalRatio(survival_rate);
1254   if (survival_rate > kYoungSurvivalRateHighThreshold) {
1255     high_survival_rate_period_length_++;
1256   } else {
1257     high_survival_rate_period_length_ = 0;
1258   }
1259 }
1260 
PerformGarbageCollection(GarbageCollector collector,const v8::GCCallbackFlags gc_callback_flags)1261 bool Heap::PerformGarbageCollection(
1262     GarbageCollector collector, const v8::GCCallbackFlags gc_callback_flags) {
1263   int freed_global_handles = 0;
1264 
1265   if (collector != SCAVENGER) {
1266     PROFILE(isolate_, CodeMovingGCEvent());
1267   }
1268 
1269 #ifdef VERIFY_HEAP
1270   if (FLAG_verify_heap) {
1271     VerifyStringTable(this);
1272   }
1273 #endif
1274 
1275   GCType gc_type =
1276       collector == MARK_COMPACTOR ? kGCTypeMarkSweepCompact : kGCTypeScavenge;
1277 
1278   {
1279     GCCallbacksScope scope(this);
1280     if (scope.CheckReenter()) {
1281       AllowHeapAllocation allow_allocation;
1282       GCTracer::Scope scope(tracer(), GCTracer::Scope::EXTERNAL);
1283       VMState<EXTERNAL> state(isolate_);
1284       HandleScope handle_scope(isolate_);
1285       CallGCPrologueCallbacks(gc_type, kNoGCCallbackFlags);
1286     }
1287   }
1288 
1289   EnsureFromSpaceIsCommitted();
1290 
1291   int start_new_space_size = Heap::new_space()->SizeAsInt();
1292 
1293   if (IsHighSurvivalRate()) {
1294     // We speed up the incremental marker if it is running so that it
1295     // does not fall behind the rate of promotion, which would cause a
1296     // constantly growing old space.
1297     incremental_marking()->NotifyOfHighPromotionRate();
1298   }
1299 
1300   {
1301     Heap::PretenuringScope pretenuring_scope(this);
1302 
1303     if (collector == MARK_COMPACTOR) {
1304       UpdateOldGenerationAllocationCounter();
1305       // Perform mark-sweep with optional compaction.
1306       MarkCompact();
1307       old_gen_exhausted_ = false;
1308       old_generation_size_configured_ = true;
1309       // This should be updated before PostGarbageCollectionProcessing, which
1310       // can cause another GC. Take into account the objects promoted during GC.
1311       old_generation_allocation_counter_ +=
1312           static_cast<size_t>(promoted_objects_size_);
1313       old_generation_size_at_last_gc_ = PromotedSpaceSizeOfObjects();
1314     } else {
1315       Scavenge();
1316     }
1317 
1318     ProcessPretenuringFeedback();
1319   }
1320 
1321   UpdateSurvivalStatistics(start_new_space_size);
1322   ConfigureInitialOldGenerationSize();
1323 
1324   isolate_->counters()->objs_since_last_young()->Set(0);
1325 
1326   if (collector != SCAVENGER) {
1327     // Callbacks that fire after this point might trigger nested GCs and
1328     // restart incremental marking, the assertion can't be moved down.
1329     DCHECK(incremental_marking()->IsStopped());
1330 
1331     // We finished a marking cycle. We can uncommit the marking deque until
1332     // we start marking again.
1333     mark_compact_collector()->marking_deque()->Uninitialize();
1334     mark_compact_collector()->EnsureMarkingDequeIsCommitted(
1335         MarkCompactCollector::kMinMarkingDequeSize);
1336   }
1337 
1338   gc_post_processing_depth_++;
1339   {
1340     AllowHeapAllocation allow_allocation;
1341     GCTracer::Scope scope(tracer(), GCTracer::Scope::EXTERNAL);
1342     freed_global_handles =
1343         isolate_->global_handles()->PostGarbageCollectionProcessing(
1344             collector, gc_callback_flags);
1345   }
1346   gc_post_processing_depth_--;
1347 
1348   isolate_->eternal_handles()->PostGarbageCollectionProcessing(this);
1349 
1350   // Update relocatables.
1351   Relocatable::PostGarbageCollectionProcessing(isolate_);
1352 
1353   double gc_speed = tracer()->CombinedMarkCompactSpeedInBytesPerMillisecond();
1354   double mutator_speed = static_cast<double>(
1355       tracer()
1356           ->CurrentOldGenerationAllocationThroughputInBytesPerMillisecond());
1357   intptr_t old_gen_size = PromotedSpaceSizeOfObjects();
1358   if (collector == MARK_COMPACTOR) {
1359     // Register the amount of external allocated memory.
1360     amount_of_external_allocated_memory_at_last_global_gc_ =
1361         amount_of_external_allocated_memory_;
1362     SetOldGenerationAllocationLimit(old_gen_size, gc_speed, mutator_speed);
1363   } else if (HasLowYoungGenerationAllocationRate() &&
1364              old_generation_size_configured_) {
1365     DampenOldGenerationAllocationLimit(old_gen_size, gc_speed, mutator_speed);
1366   }
1367 
1368   {
1369     GCCallbacksScope scope(this);
1370     if (scope.CheckReenter()) {
1371       AllowHeapAllocation allow_allocation;
1372       GCTracer::Scope scope(tracer(), GCTracer::Scope::EXTERNAL);
1373       VMState<EXTERNAL> state(isolate_);
1374       HandleScope handle_scope(isolate_);
1375       CallGCEpilogueCallbacks(gc_type, gc_callback_flags);
1376     }
1377   }
1378 
1379 #ifdef VERIFY_HEAP
1380   if (FLAG_verify_heap) {
1381     VerifyStringTable(this);
1382   }
1383 #endif
1384 
1385   return freed_global_handles > 0;
1386 }
1387 
1388 
CallGCPrologueCallbacks(GCType gc_type,GCCallbackFlags flags)1389 void Heap::CallGCPrologueCallbacks(GCType gc_type, GCCallbackFlags flags) {
1390   for (int i = 0; i < gc_prologue_callbacks_.length(); ++i) {
1391     if (gc_type & gc_prologue_callbacks_[i].gc_type) {
1392       if (!gc_prologue_callbacks_[i].pass_isolate) {
1393         v8::GCCallback callback = reinterpret_cast<v8::GCCallback>(
1394             gc_prologue_callbacks_[i].callback);
1395         callback(gc_type, flags);
1396       } else {
1397         v8::Isolate* isolate = reinterpret_cast<v8::Isolate*>(this->isolate());
1398         gc_prologue_callbacks_[i].callback(isolate, gc_type, flags);
1399       }
1400     }
1401   }
1402 }
1403 
1404 
CallGCEpilogueCallbacks(GCType gc_type,GCCallbackFlags gc_callback_flags)1405 void Heap::CallGCEpilogueCallbacks(GCType gc_type,
1406                                    GCCallbackFlags gc_callback_flags) {
1407   for (int i = 0; i < gc_epilogue_callbacks_.length(); ++i) {
1408     if (gc_type & gc_epilogue_callbacks_[i].gc_type) {
1409       if (!gc_epilogue_callbacks_[i].pass_isolate) {
1410         v8::GCCallback callback = reinterpret_cast<v8::GCCallback>(
1411             gc_epilogue_callbacks_[i].callback);
1412         callback(gc_type, gc_callback_flags);
1413       } else {
1414         v8::Isolate* isolate = reinterpret_cast<v8::Isolate*>(this->isolate());
1415         gc_epilogue_callbacks_[i].callback(isolate, gc_type, gc_callback_flags);
1416       }
1417     }
1418   }
1419 }
1420 
1421 
MarkCompact()1422 void Heap::MarkCompact() {
1423   PauseInlineAllocationObserversScope pause_observers(new_space());
1424 
1425   gc_state_ = MARK_COMPACT;
1426   LOG(isolate_, ResourceEvent("markcompact", "begin"));
1427 
1428   uint64_t size_of_objects_before_gc = SizeOfObjects();
1429 
1430   mark_compact_collector()->Prepare();
1431 
1432   ms_count_++;
1433 
1434   MarkCompactPrologue();
1435 
1436   mark_compact_collector()->CollectGarbage();
1437 
1438   LOG(isolate_, ResourceEvent("markcompact", "end"));
1439 
1440   MarkCompactEpilogue();
1441 
1442   if (FLAG_allocation_site_pretenuring) {
1443     EvaluateOldSpaceLocalPretenuring(size_of_objects_before_gc);
1444   }
1445 }
1446 
1447 
MarkCompactEpilogue()1448 void Heap::MarkCompactEpilogue() {
1449   gc_state_ = NOT_IN_GC;
1450 
1451   isolate_->counters()->objs_since_last_full()->Set(0);
1452 
1453   incremental_marking()->Epilogue();
1454 
1455   PreprocessStackTraces();
1456 }
1457 
1458 
MarkCompactPrologue()1459 void Heap::MarkCompactPrologue() {
1460   // At any old GC clear the keyed lookup cache to enable collection of unused
1461   // maps.
1462   isolate_->keyed_lookup_cache()->Clear();
1463   isolate_->context_slot_cache()->Clear();
1464   isolate_->descriptor_lookup_cache()->Clear();
1465   RegExpResultsCache::Clear(string_split_cache());
1466   RegExpResultsCache::Clear(regexp_multiple_cache());
1467 
1468   isolate_->compilation_cache()->MarkCompactPrologue();
1469 
1470   CompletelyClearInstanceofCache();
1471 
1472   FlushNumberStringCache();
1473   if (FLAG_cleanup_code_caches_at_gc) {
1474     polymorphic_code_cache()->set_cache(undefined_value());
1475   }
1476 
1477   ClearNormalizedMapCaches();
1478 }
1479 
1480 
1481 #ifdef VERIFY_HEAP
1482 // Visitor class to verify pointers in code or data space do not point into
1483 // new space.
1484 class VerifyNonPointerSpacePointersVisitor : public ObjectVisitor {
1485  public:
VerifyNonPointerSpacePointersVisitor(Heap * heap)1486   explicit VerifyNonPointerSpacePointersVisitor(Heap* heap) : heap_(heap) {}
1487 
VisitPointers(Object ** start,Object ** end)1488   void VisitPointers(Object** start, Object** end) override {
1489     for (Object** current = start; current < end; current++) {
1490       if ((*current)->IsHeapObject()) {
1491         CHECK(!heap_->InNewSpace(HeapObject::cast(*current)));
1492       }
1493     }
1494   }
1495 
1496  private:
1497   Heap* heap_;
1498 };
1499 
1500 
VerifyNonPointerSpacePointers(Heap * heap)1501 static void VerifyNonPointerSpacePointers(Heap* heap) {
1502   // Verify that there are no pointers to new space in spaces where we
1503   // do not expect them.
1504   VerifyNonPointerSpacePointersVisitor v(heap);
1505   HeapObjectIterator code_it(heap->code_space());
1506   for (HeapObject* object = code_it.Next(); object != NULL;
1507        object = code_it.Next())
1508     object->Iterate(&v);
1509 }
1510 #endif  // VERIFY_HEAP
1511 
1512 
CheckNewSpaceExpansionCriteria()1513 void Heap::CheckNewSpaceExpansionCriteria() {
1514   if (FLAG_experimental_new_space_growth_heuristic) {
1515     if (new_space_.TotalCapacity() < new_space_.MaximumCapacity() &&
1516         survived_last_scavenge_ * 100 / new_space_.TotalCapacity() >= 10) {
1517       // Grow the size of new space if there is room to grow, and more than 10%
1518       // have survived the last scavenge.
1519       new_space_.Grow();
1520       survived_since_last_expansion_ = 0;
1521     }
1522   } else if (new_space_.TotalCapacity() < new_space_.MaximumCapacity() &&
1523              survived_since_last_expansion_ > new_space_.TotalCapacity()) {
1524     // Grow the size of new space if there is room to grow, and enough data
1525     // has survived scavenge since the last expansion.
1526     new_space_.Grow();
1527     survived_since_last_expansion_ = 0;
1528   }
1529 }
1530 
1531 
IsUnscavengedHeapObject(Heap * heap,Object ** p)1532 static bool IsUnscavengedHeapObject(Heap* heap, Object** p) {
1533   return heap->InNewSpace(*p) &&
1534          !HeapObject::cast(*p)->map_word().IsForwardingAddress();
1535 }
1536 
1537 
IsUnmodifiedHeapObject(Object ** p)1538 static bool IsUnmodifiedHeapObject(Object** p) {
1539   Object* object = *p;
1540   if (object->IsSmi()) return false;
1541   HeapObject* heap_object = HeapObject::cast(object);
1542   if (!object->IsJSObject()) return false;
1543   Object* obj_constructor = (JSObject::cast(object))->map()->GetConstructor();
1544   if (!obj_constructor->IsJSFunction()) return false;
1545   JSFunction* constructor = JSFunction::cast(obj_constructor);
1546   if (!constructor->shared()->IsApiFunction()) return false;
1547   if (constructor != nullptr &&
1548       constructor->initial_map() == heap_object->map()) {
1549     return true;
1550   }
1551   return false;
1552 }
1553 
1554 
ScavengeStoreBufferCallback(Heap * heap,MemoryChunk * page,StoreBufferEvent event)1555 void Heap::ScavengeStoreBufferCallback(Heap* heap, MemoryChunk* page,
1556                                        StoreBufferEvent event) {
1557   heap->store_buffer_rebuilder_.Callback(page, event);
1558 }
1559 
1560 
Initialize()1561 void PromotionQueue::Initialize() {
1562   // The last to-space page may be used for promotion queue. On promotion
1563   // conflict, we use the emergency stack.
1564   DCHECK((Page::kPageSize - MemoryChunk::kBodyOffset) % (2 * kPointerSize) ==
1565          0);
1566   front_ = rear_ =
1567       reinterpret_cast<intptr_t*>(heap_->new_space()->ToSpaceEnd());
1568   limit_ = reinterpret_cast<intptr_t*>(
1569       Page::FromAllocationTop(reinterpret_cast<Address>(rear_))->area_start());
1570   emergency_stack_ = NULL;
1571 }
1572 
1573 
RelocateQueueHead()1574 void PromotionQueue::RelocateQueueHead() {
1575   DCHECK(emergency_stack_ == NULL);
1576 
1577   Page* p = Page::FromAllocationTop(reinterpret_cast<Address>(rear_));
1578   intptr_t* head_start = rear_;
1579   intptr_t* head_end = Min(front_, reinterpret_cast<intptr_t*>(p->area_end()));
1580 
1581   int entries_count =
1582       static_cast<int>(head_end - head_start) / kEntrySizeInWords;
1583 
1584   emergency_stack_ = new List<Entry>(2 * entries_count);
1585 
1586   while (head_start != head_end) {
1587     int size = static_cast<int>(*(head_start++));
1588     HeapObject* obj = reinterpret_cast<HeapObject*>(*(head_start++));
1589     // New space allocation in SemiSpaceCopyObject marked the region
1590     // overlapping with promotion queue as uninitialized.
1591     MSAN_MEMORY_IS_INITIALIZED(&size, sizeof(size));
1592     MSAN_MEMORY_IS_INITIALIZED(&obj, sizeof(obj));
1593     emergency_stack_->Add(Entry(obj, size));
1594   }
1595   rear_ = head_end;
1596 }
1597 
1598 
1599 class ScavengeWeakObjectRetainer : public WeakObjectRetainer {
1600  public:
ScavengeWeakObjectRetainer(Heap * heap)1601   explicit ScavengeWeakObjectRetainer(Heap* heap) : heap_(heap) {}
1602 
RetainAs(Object * object)1603   virtual Object* RetainAs(Object* object) {
1604     if (!heap_->InFromSpace(object)) {
1605       return object;
1606     }
1607 
1608     MapWord map_word = HeapObject::cast(object)->map_word();
1609     if (map_word.IsForwardingAddress()) {
1610       return map_word.ToForwardingAddress();
1611     }
1612     return NULL;
1613   }
1614 
1615  private:
1616   Heap* heap_;
1617 };
1618 
1619 
Scavenge()1620 void Heap::Scavenge() {
1621   GCTracer::Scope gc_scope(tracer(), GCTracer::Scope::SCAVENGER_SCAVENGE);
1622   RelocationLock relocation_lock(this);
1623   // There are soft limits in the allocation code, designed to trigger a mark
1624   // sweep collection by failing allocations. There is no sense in trying to
1625   // trigger one during scavenge: scavenges allocation should always succeed.
1626   AlwaysAllocateScope scope(isolate());
1627 
1628   // Bump-pointer allocations done during scavenge are not real allocations.
1629   // Pause the inline allocation steps.
1630   PauseInlineAllocationObserversScope pause_observers(new_space());
1631 
1632 #ifdef VERIFY_HEAP
1633   if (FLAG_verify_heap) VerifyNonPointerSpacePointers(this);
1634 #endif
1635 
1636   gc_state_ = SCAVENGE;
1637 
1638   // Implements Cheney's copying algorithm
1639   LOG(isolate_, ResourceEvent("scavenge", "begin"));
1640 
1641   // Clear descriptor cache.
1642   isolate_->descriptor_lookup_cache()->Clear();
1643 
1644   // Used for updating survived_since_last_expansion_ at function end.
1645   intptr_t survived_watermark = PromotedSpaceSizeOfObjects();
1646 
1647   scavenge_collector_->SelectScavengingVisitorsTable();
1648 
1649   array_buffer_tracker()->PrepareDiscoveryInNewSpace();
1650 
1651   // Flip the semispaces.  After flipping, to space is empty, from space has
1652   // live objects.
1653   new_space_.Flip();
1654   new_space_.ResetAllocationInfo();
1655 
1656   // We need to sweep newly copied objects which can be either in the
1657   // to space or promoted to the old generation.  For to-space
1658   // objects, we treat the bottom of the to space as a queue.  Newly
1659   // copied and unswept objects lie between a 'front' mark and the
1660   // allocation pointer.
1661   //
1662   // Promoted objects can go into various old-generation spaces, and
1663   // can be allocated internally in the spaces (from the free list).
1664   // We treat the top of the to space as a queue of addresses of
1665   // promoted objects.  The addresses of newly promoted and unswept
1666   // objects lie between a 'front' mark and a 'rear' mark that is
1667   // updated as a side effect of promoting an object.
1668   //
1669   // There is guaranteed to be enough room at the top of the to space
1670   // for the addresses of promoted objects: every object promoted
1671   // frees up its size in bytes from the top of the new space, and
1672   // objects are at least one pointer in size.
1673   Address new_space_front = new_space_.ToSpaceStart();
1674   promotion_queue_.Initialize();
1675 
1676   ScavengeVisitor scavenge_visitor(this);
1677 
1678   if (FLAG_scavenge_reclaim_unmodified_objects) {
1679     isolate()->global_handles()->IdentifyWeakUnmodifiedObjects(
1680         &IsUnmodifiedHeapObject);
1681   }
1682 
1683   {
1684     // Copy roots.
1685     GCTracer::Scope gc_scope(tracer(), GCTracer::Scope::SCAVENGER_ROOTS);
1686     IterateRoots(&scavenge_visitor, VISIT_ALL_IN_SCAVENGE);
1687   }
1688 
1689   {
1690     // Copy objects reachable from the old generation.
1691     GCTracer::Scope gc_scope(tracer(),
1692                              GCTracer::Scope::SCAVENGER_OLD_TO_NEW_POINTERS);
1693     StoreBufferRebuildScope scope(this, store_buffer(),
1694                                   &ScavengeStoreBufferCallback);
1695     store_buffer()->IteratePointersToNewSpace(&Scavenger::ScavengeObject);
1696   }
1697 
1698   {
1699     GCTracer::Scope gc_scope(tracer(), GCTracer::Scope::SCAVENGER_WEAK);
1700     // Copy objects reachable from the encountered weak collections list.
1701     scavenge_visitor.VisitPointer(&encountered_weak_collections_);
1702     // Copy objects reachable from the encountered weak cells.
1703     scavenge_visitor.VisitPointer(&encountered_weak_cells_);
1704   }
1705 
1706   {
1707     // Copy objects reachable from the code flushing candidates list.
1708     GCTracer::Scope gc_scope(tracer(),
1709                              GCTracer::Scope::SCAVENGER_CODE_FLUSH_CANDIDATES);
1710     MarkCompactCollector* collector = mark_compact_collector();
1711     if (collector->is_code_flushing_enabled()) {
1712       collector->code_flusher()->IteratePointersToFromSpace(&scavenge_visitor);
1713     }
1714   }
1715 
1716   {
1717     GCTracer::Scope gc_scope(tracer(), GCTracer::Scope::SCAVENGER_SEMISPACE);
1718     new_space_front = DoScavenge(&scavenge_visitor, new_space_front);
1719   }
1720 
1721   if (FLAG_scavenge_reclaim_unmodified_objects) {
1722     isolate()->global_handles()->MarkNewSpaceWeakUnmodifiedObjectsPending(
1723         &IsUnscavengedHeapObject);
1724 
1725     isolate()->global_handles()->IterateNewSpaceWeakUnmodifiedRoots(
1726         &scavenge_visitor);
1727     new_space_front = DoScavenge(&scavenge_visitor, new_space_front);
1728   } else {
1729     GCTracer::Scope gc_scope(tracer(),
1730                              GCTracer::Scope::SCAVENGER_OBJECT_GROUPS);
1731     while (isolate()->global_handles()->IterateObjectGroups(
1732         &scavenge_visitor, &IsUnscavengedHeapObject)) {
1733       new_space_front = DoScavenge(&scavenge_visitor, new_space_front);
1734     }
1735     isolate()->global_handles()->RemoveObjectGroups();
1736     isolate()->global_handles()->RemoveImplicitRefGroups();
1737 
1738     isolate()->global_handles()->IdentifyNewSpaceWeakIndependentHandles(
1739         &IsUnscavengedHeapObject);
1740 
1741     isolate()->global_handles()->IterateNewSpaceWeakIndependentRoots(
1742         &scavenge_visitor);
1743     new_space_front = DoScavenge(&scavenge_visitor, new_space_front);
1744   }
1745 
1746   UpdateNewSpaceReferencesInExternalStringTable(
1747       &UpdateNewSpaceReferenceInExternalStringTableEntry);
1748 
1749   promotion_queue_.Destroy();
1750 
1751   incremental_marking()->UpdateMarkingDequeAfterScavenge();
1752 
1753   ScavengeWeakObjectRetainer weak_object_retainer(this);
1754   ProcessYoungWeakReferences(&weak_object_retainer);
1755 
1756   DCHECK(new_space_front == new_space_.top());
1757 
1758   // Set age mark.
1759   new_space_.set_age_mark(new_space_.top());
1760 
1761   array_buffer_tracker()->FreeDead(true);
1762 
1763   // Update how much has survived scavenge.
1764   IncrementYoungSurvivorsCounter(static_cast<int>(
1765       (PromotedSpaceSizeOfObjects() - survived_watermark) + new_space_.Size()));
1766 
1767   LOG(isolate_, ResourceEvent("scavenge", "end"));
1768 
1769   gc_state_ = NOT_IN_GC;
1770 }
1771 
1772 
UpdateNewSpaceReferenceInExternalStringTableEntry(Heap * heap,Object ** p)1773 String* Heap::UpdateNewSpaceReferenceInExternalStringTableEntry(Heap* heap,
1774                                                                 Object** p) {
1775   MapWord first_word = HeapObject::cast(*p)->map_word();
1776 
1777   if (!first_word.IsForwardingAddress()) {
1778     // Unreachable external string can be finalized.
1779     heap->FinalizeExternalString(String::cast(*p));
1780     return NULL;
1781   }
1782 
1783   // String is still reachable.
1784   return String::cast(first_word.ToForwardingAddress());
1785 }
1786 
1787 
UpdateNewSpaceReferencesInExternalStringTable(ExternalStringTableUpdaterCallback updater_func)1788 void Heap::UpdateNewSpaceReferencesInExternalStringTable(
1789     ExternalStringTableUpdaterCallback updater_func) {
1790 #ifdef VERIFY_HEAP
1791   if (FLAG_verify_heap) {
1792     external_string_table_.Verify();
1793   }
1794 #endif
1795 
1796   if (external_string_table_.new_space_strings_.is_empty()) return;
1797 
1798   Object** start = &external_string_table_.new_space_strings_[0];
1799   Object** end = start + external_string_table_.new_space_strings_.length();
1800   Object** last = start;
1801 
1802   for (Object** p = start; p < end; ++p) {
1803     DCHECK(InFromSpace(*p));
1804     String* target = updater_func(this, p);
1805 
1806     if (target == NULL) continue;
1807 
1808     DCHECK(target->IsExternalString());
1809 
1810     if (InNewSpace(target)) {
1811       // String is still in new space.  Update the table entry.
1812       *last = target;
1813       ++last;
1814     } else {
1815       // String got promoted.  Move it to the old string list.
1816       external_string_table_.AddOldString(target);
1817     }
1818   }
1819 
1820   DCHECK(last <= end);
1821   external_string_table_.ShrinkNewStrings(static_cast<int>(last - start));
1822 }
1823 
1824 
UpdateReferencesInExternalStringTable(ExternalStringTableUpdaterCallback updater_func)1825 void Heap::UpdateReferencesInExternalStringTable(
1826     ExternalStringTableUpdaterCallback updater_func) {
1827   // Update old space string references.
1828   if (external_string_table_.old_space_strings_.length() > 0) {
1829     Object** start = &external_string_table_.old_space_strings_[0];
1830     Object** end = start + external_string_table_.old_space_strings_.length();
1831     for (Object** p = start; p < end; ++p) *p = updater_func(this, p);
1832   }
1833 
1834   UpdateNewSpaceReferencesInExternalStringTable(updater_func);
1835 }
1836 
1837 
ProcessAllWeakReferences(WeakObjectRetainer * retainer)1838 void Heap::ProcessAllWeakReferences(WeakObjectRetainer* retainer) {
1839   ProcessNativeContexts(retainer);
1840   ProcessAllocationSites(retainer);
1841 }
1842 
1843 
ProcessYoungWeakReferences(WeakObjectRetainer * retainer)1844 void Heap::ProcessYoungWeakReferences(WeakObjectRetainer* retainer) {
1845   ProcessNativeContexts(retainer);
1846 }
1847 
1848 
ProcessNativeContexts(WeakObjectRetainer * retainer)1849 void Heap::ProcessNativeContexts(WeakObjectRetainer* retainer) {
1850   Object* head = VisitWeakList<Context>(this, native_contexts_list(), retainer);
1851   // Update the head of the list of contexts.
1852   set_native_contexts_list(head);
1853 }
1854 
1855 
ProcessAllocationSites(WeakObjectRetainer * retainer)1856 void Heap::ProcessAllocationSites(WeakObjectRetainer* retainer) {
1857   Object* allocation_site_obj =
1858       VisitWeakList<AllocationSite>(this, allocation_sites_list(), retainer);
1859   set_allocation_sites_list(allocation_site_obj);
1860 }
1861 
1862 
ResetAllAllocationSitesDependentCode(PretenureFlag flag)1863 void Heap::ResetAllAllocationSitesDependentCode(PretenureFlag flag) {
1864   DisallowHeapAllocation no_allocation_scope;
1865   Object* cur = allocation_sites_list();
1866   bool marked = false;
1867   while (cur->IsAllocationSite()) {
1868     AllocationSite* casted = AllocationSite::cast(cur);
1869     if (casted->GetPretenureMode() == flag) {
1870       casted->ResetPretenureDecision();
1871       casted->set_deopt_dependent_code(true);
1872       marked = true;
1873       RemoveAllocationSitePretenuringFeedback(casted);
1874     }
1875     cur = casted->weak_next();
1876   }
1877   if (marked) isolate_->stack_guard()->RequestDeoptMarkedAllocationSites();
1878 }
1879 
1880 
EvaluateOldSpaceLocalPretenuring(uint64_t size_of_objects_before_gc)1881 void Heap::EvaluateOldSpaceLocalPretenuring(
1882     uint64_t size_of_objects_before_gc) {
1883   uint64_t size_of_objects_after_gc = SizeOfObjects();
1884   double old_generation_survival_rate =
1885       (static_cast<double>(size_of_objects_after_gc) * 100) /
1886       static_cast<double>(size_of_objects_before_gc);
1887 
1888   if (old_generation_survival_rate < kOldSurvivalRateLowThreshold) {
1889     // Too many objects died in the old generation, pretenuring of wrong
1890     // allocation sites may be the cause for that. We have to deopt all
1891     // dependent code registered in the allocation sites to re-evaluate
1892     // our pretenuring decisions.
1893     ResetAllAllocationSitesDependentCode(TENURED);
1894     if (FLAG_trace_pretenuring) {
1895       PrintF(
1896           "Deopt all allocation sites dependent code due to low survival "
1897           "rate in the old generation %f\n",
1898           old_generation_survival_rate);
1899     }
1900   }
1901 }
1902 
1903 
VisitExternalResources(v8::ExternalResourceVisitor * visitor)1904 void Heap::VisitExternalResources(v8::ExternalResourceVisitor* visitor) {
1905   DisallowHeapAllocation no_allocation;
1906   // All external strings are listed in the external string table.
1907 
1908   class ExternalStringTableVisitorAdapter : public ObjectVisitor {
1909    public:
1910     explicit ExternalStringTableVisitorAdapter(
1911         v8::ExternalResourceVisitor* visitor)
1912         : visitor_(visitor) {}
1913     virtual void VisitPointers(Object** start, Object** end) {
1914       for (Object** p = start; p < end; p++) {
1915         DCHECK((*p)->IsExternalString());
1916         visitor_->VisitExternalString(
1917             Utils::ToLocal(Handle<String>(String::cast(*p))));
1918       }
1919     }
1920 
1921    private:
1922     v8::ExternalResourceVisitor* visitor_;
1923   } external_string_table_visitor(visitor);
1924 
1925   external_string_table_.Iterate(&external_string_table_visitor);
1926 }
1927 
1928 
DoScavenge(ObjectVisitor * scavenge_visitor,Address new_space_front)1929 Address Heap::DoScavenge(ObjectVisitor* scavenge_visitor,
1930                          Address new_space_front) {
1931   do {
1932     SemiSpace::AssertValidRange(new_space_front, new_space_.top());
1933     // The addresses new_space_front and new_space_.top() define a
1934     // queue of unprocessed copied objects.  Process them until the
1935     // queue is empty.
1936     while (new_space_front != new_space_.top()) {
1937       if (!NewSpacePage::IsAtEnd(new_space_front)) {
1938         HeapObject* object = HeapObject::FromAddress(new_space_front);
1939         new_space_front +=
1940             StaticScavengeVisitor::IterateBody(object->map(), object);
1941       } else {
1942         new_space_front =
1943             NewSpacePage::FromLimit(new_space_front)->next_page()->area_start();
1944       }
1945     }
1946 
1947     // Promote and process all the to-be-promoted objects.
1948     {
1949       StoreBufferRebuildScope scope(this, store_buffer(),
1950                                     &ScavengeStoreBufferCallback);
1951       while (!promotion_queue()->is_empty()) {
1952         HeapObject* target;
1953         int size;
1954         promotion_queue()->remove(&target, &size);
1955 
1956         // Promoted object might be already partially visited
1957         // during old space pointer iteration. Thus we search specifically
1958         // for pointers to from semispace instead of looking for pointers
1959         // to new space.
1960         DCHECK(!target->IsMap());
1961 
1962         IteratePointersToFromSpace(target, size, &Scavenger::ScavengeObject);
1963       }
1964     }
1965 
1966     // Take another spin if there are now unswept objects in new space
1967     // (there are currently no more unswept promoted objects).
1968   } while (new_space_front != new_space_.top());
1969 
1970   return new_space_front;
1971 }
1972 
1973 
1974 STATIC_ASSERT((FixedDoubleArray::kHeaderSize & kDoubleAlignmentMask) ==
1975               0);  // NOLINT
1976 STATIC_ASSERT((FixedTypedArrayBase::kDataOffset & kDoubleAlignmentMask) ==
1977               0);  // NOLINT
1978 #ifdef V8_HOST_ARCH_32_BIT
1979 STATIC_ASSERT((HeapNumber::kValueOffset & kDoubleAlignmentMask) !=
1980               0);  // NOLINT
1981 #endif
1982 
1983 
GetMaximumFillToAlign(AllocationAlignment alignment)1984 int Heap::GetMaximumFillToAlign(AllocationAlignment alignment) {
1985   switch (alignment) {
1986     case kWordAligned:
1987       return 0;
1988     case kDoubleAligned:
1989     case kDoubleUnaligned:
1990       return kDoubleSize - kPointerSize;
1991     case kSimd128Unaligned:
1992       return kSimd128Size - kPointerSize;
1993     default:
1994       UNREACHABLE();
1995   }
1996   return 0;
1997 }
1998 
1999 
GetFillToAlign(Address address,AllocationAlignment alignment)2000 int Heap::GetFillToAlign(Address address, AllocationAlignment alignment) {
2001   intptr_t offset = OffsetFrom(address);
2002   if (alignment == kDoubleAligned && (offset & kDoubleAlignmentMask) != 0)
2003     return kPointerSize;
2004   if (alignment == kDoubleUnaligned && (offset & kDoubleAlignmentMask) == 0)
2005     return kDoubleSize - kPointerSize;  // No fill if double is always aligned.
2006   if (alignment == kSimd128Unaligned) {
2007     return (kSimd128Size - (static_cast<int>(offset) + kPointerSize)) &
2008            kSimd128AlignmentMask;
2009   }
2010   return 0;
2011 }
2012 
2013 
PrecedeWithFiller(HeapObject * object,int filler_size)2014 HeapObject* Heap::PrecedeWithFiller(HeapObject* object, int filler_size) {
2015   CreateFillerObjectAt(object->address(), filler_size);
2016   return HeapObject::FromAddress(object->address() + filler_size);
2017 }
2018 
2019 
AlignWithFiller(HeapObject * object,int object_size,int allocation_size,AllocationAlignment alignment)2020 HeapObject* Heap::AlignWithFiller(HeapObject* object, int object_size,
2021                                   int allocation_size,
2022                                   AllocationAlignment alignment) {
2023   int filler_size = allocation_size - object_size;
2024   DCHECK(filler_size > 0);
2025   int pre_filler = GetFillToAlign(object->address(), alignment);
2026   if (pre_filler) {
2027     object = PrecedeWithFiller(object, pre_filler);
2028     filler_size -= pre_filler;
2029   }
2030   if (filler_size)
2031     CreateFillerObjectAt(object->address() + object_size, filler_size);
2032   return object;
2033 }
2034 
2035 
DoubleAlignForDeserialization(HeapObject * object,int size)2036 HeapObject* Heap::DoubleAlignForDeserialization(HeapObject* object, int size) {
2037   return AlignWithFiller(object, size - kPointerSize, size, kDoubleAligned);
2038 }
2039 
2040 
RegisterNewArrayBuffer(JSArrayBuffer * buffer)2041 void Heap::RegisterNewArrayBuffer(JSArrayBuffer* buffer) {
2042   return array_buffer_tracker()->RegisterNew(buffer);
2043 }
2044 
2045 
UnregisterArrayBuffer(JSArrayBuffer * buffer)2046 void Heap::UnregisterArrayBuffer(JSArrayBuffer* buffer) {
2047   return array_buffer_tracker()->Unregister(buffer);
2048 }
2049 
2050 
ConfigureInitialOldGenerationSize()2051 void Heap::ConfigureInitialOldGenerationSize() {
2052   if (!old_generation_size_configured_ && tracer()->SurvivalEventsRecorded()) {
2053     old_generation_allocation_limit_ =
2054         Max(kMinimumOldGenerationAllocationLimit,
2055             static_cast<intptr_t>(
2056                 static_cast<double>(old_generation_allocation_limit_) *
2057                 (tracer()->AverageSurvivalRatio() / 100)));
2058   }
2059 }
2060 
2061 
AllocatePartialMap(InstanceType instance_type,int instance_size)2062 AllocationResult Heap::AllocatePartialMap(InstanceType instance_type,
2063                                           int instance_size) {
2064   Object* result = nullptr;
2065   AllocationResult allocation = AllocateRaw(Map::kSize, MAP_SPACE);
2066   if (!allocation.To(&result)) return allocation;
2067 
2068   // Map::cast cannot be used due to uninitialized map field.
2069   reinterpret_cast<Map*>(result)->set_map(
2070       reinterpret_cast<Map*>(root(kMetaMapRootIndex)));
2071   reinterpret_cast<Map*>(result)->set_instance_type(instance_type);
2072   reinterpret_cast<Map*>(result)->set_instance_size(instance_size);
2073   // Initialize to only containing tagged fields.
2074   reinterpret_cast<Map*>(result)->set_visitor_id(
2075       StaticVisitorBase::GetVisitorId(instance_type, instance_size, false));
2076   if (FLAG_unbox_double_fields) {
2077     reinterpret_cast<Map*>(result)
2078         ->set_layout_descriptor(LayoutDescriptor::FastPointerLayout());
2079   }
2080   reinterpret_cast<Map*>(result)->clear_unused();
2081   reinterpret_cast<Map*>(result)
2082       ->set_inobject_properties_or_constructor_function_index(0);
2083   reinterpret_cast<Map*>(result)->set_unused_property_fields(0);
2084   reinterpret_cast<Map*>(result)->set_bit_field(0);
2085   reinterpret_cast<Map*>(result)->set_bit_field2(0);
2086   int bit_field3 = Map::EnumLengthBits::encode(kInvalidEnumCacheSentinel) |
2087                    Map::OwnsDescriptors::encode(true) |
2088                    Map::ConstructionCounter::encode(Map::kNoSlackTracking);
2089   reinterpret_cast<Map*>(result)->set_bit_field3(bit_field3);
2090   reinterpret_cast<Map*>(result)->set_weak_cell_cache(Smi::FromInt(0));
2091   return result;
2092 }
2093 
2094 
AllocateMap(InstanceType instance_type,int instance_size,ElementsKind elements_kind)2095 AllocationResult Heap::AllocateMap(InstanceType instance_type,
2096                                    int instance_size,
2097                                    ElementsKind elements_kind) {
2098   HeapObject* result = nullptr;
2099   AllocationResult allocation = AllocateRaw(Map::kSize, MAP_SPACE);
2100   if (!allocation.To(&result)) return allocation;
2101 
2102   result->set_map_no_write_barrier(meta_map());
2103   Map* map = Map::cast(result);
2104   map->set_instance_type(instance_type);
2105   map->set_prototype(null_value(), SKIP_WRITE_BARRIER);
2106   map->set_constructor_or_backpointer(null_value(), SKIP_WRITE_BARRIER);
2107   map->set_instance_size(instance_size);
2108   map->clear_unused();
2109   map->set_inobject_properties_or_constructor_function_index(0);
2110   map->set_code_cache(empty_fixed_array(), SKIP_WRITE_BARRIER);
2111   map->set_dependent_code(DependentCode::cast(empty_fixed_array()),
2112                           SKIP_WRITE_BARRIER);
2113   map->set_weak_cell_cache(Smi::FromInt(0));
2114   map->set_raw_transitions(Smi::FromInt(0));
2115   map->set_unused_property_fields(0);
2116   map->set_instance_descriptors(empty_descriptor_array());
2117   if (FLAG_unbox_double_fields) {
2118     map->set_layout_descriptor(LayoutDescriptor::FastPointerLayout());
2119   }
2120   // Must be called only after |instance_type|, |instance_size| and
2121   // |layout_descriptor| are set.
2122   map->set_visitor_id(Heap::GetStaticVisitorIdForMap(map));
2123   map->set_bit_field(0);
2124   map->set_bit_field2(1 << Map::kIsExtensible);
2125   int bit_field3 = Map::EnumLengthBits::encode(kInvalidEnumCacheSentinel) |
2126                    Map::OwnsDescriptors::encode(true) |
2127                    Map::ConstructionCounter::encode(Map::kNoSlackTracking);
2128   map->set_bit_field3(bit_field3);
2129   map->set_elements_kind(elements_kind);
2130   map->set_new_target_is_base(true);
2131 
2132   return map;
2133 }
2134 
2135 
AllocateFillerObject(int size,bool double_align,AllocationSpace space)2136 AllocationResult Heap::AllocateFillerObject(int size, bool double_align,
2137                                             AllocationSpace space) {
2138   HeapObject* obj = nullptr;
2139   {
2140     AllocationAlignment align = double_align ? kDoubleAligned : kWordAligned;
2141     AllocationResult allocation = AllocateRaw(size, space, align);
2142     if (!allocation.To(&obj)) return allocation;
2143   }
2144 #ifdef DEBUG
2145   MemoryChunk* chunk = MemoryChunk::FromAddress(obj->address());
2146   DCHECK(chunk->owner()->identity() == space);
2147 #endif
2148   CreateFillerObjectAt(obj->address(), size);
2149   return obj;
2150 }
2151 
2152 
2153 const Heap::StringTypeTable Heap::string_type_table[] = {
2154 #define STRING_TYPE_ELEMENT(type, size, name, camel_name) \
2155   { type, size, k##camel_name##MapRootIndex }             \
2156   ,
2157     STRING_TYPE_LIST(STRING_TYPE_ELEMENT)
2158 #undef STRING_TYPE_ELEMENT
2159 };
2160 
2161 
2162 const Heap::ConstantStringTable Heap::constant_string_table[] = {
2163     {"", kempty_stringRootIndex},
2164 #define CONSTANT_STRING_ELEMENT(name, contents) \
2165   { contents, k##name##RootIndex }              \
2166   ,
2167     INTERNALIZED_STRING_LIST(CONSTANT_STRING_ELEMENT)
2168 #undef CONSTANT_STRING_ELEMENT
2169 };
2170 
2171 
2172 const Heap::StructTable Heap::struct_table[] = {
2173 #define STRUCT_TABLE_ELEMENT(NAME, Name, name)        \
2174   { NAME##_TYPE, Name::kSize, k##Name##MapRootIndex } \
2175   ,
2176     STRUCT_LIST(STRUCT_TABLE_ELEMENT)
2177 #undef STRUCT_TABLE_ELEMENT
2178 };
2179 
2180 
CreateInitialMaps()2181 bool Heap::CreateInitialMaps() {
2182   HeapObject* obj = nullptr;
2183   {
2184     AllocationResult allocation = AllocatePartialMap(MAP_TYPE, Map::kSize);
2185     if (!allocation.To(&obj)) return false;
2186   }
2187   // Map::cast cannot be used due to uninitialized map field.
2188   Map* new_meta_map = reinterpret_cast<Map*>(obj);
2189   set_meta_map(new_meta_map);
2190   new_meta_map->set_map(new_meta_map);
2191 
2192   {  // Partial map allocation
2193 #define ALLOCATE_PARTIAL_MAP(instance_type, size, field_name)                \
2194   {                                                                          \
2195     Map* map;                                                                \
2196     if (!AllocatePartialMap((instance_type), (size)).To(&map)) return false; \
2197     set_##field_name##_map(map);                                             \
2198   }
2199 
2200     ALLOCATE_PARTIAL_MAP(FIXED_ARRAY_TYPE, kVariableSizeSentinel, fixed_array);
2201     ALLOCATE_PARTIAL_MAP(ODDBALL_TYPE, Oddball::kSize, undefined);
2202     ALLOCATE_PARTIAL_MAP(ODDBALL_TYPE, Oddball::kSize, null);
2203 
2204 #undef ALLOCATE_PARTIAL_MAP
2205   }
2206 
2207   // Allocate the empty array.
2208   {
2209     AllocationResult allocation = AllocateEmptyFixedArray();
2210     if (!allocation.To(&obj)) return false;
2211   }
2212   set_empty_fixed_array(FixedArray::cast(obj));
2213 
2214   {
2215     AllocationResult allocation = Allocate(null_map(), OLD_SPACE);
2216     if (!allocation.To(&obj)) return false;
2217   }
2218   set_null_value(Oddball::cast(obj));
2219   Oddball::cast(obj)->set_kind(Oddball::kNull);
2220 
2221   {
2222     AllocationResult allocation = Allocate(undefined_map(), OLD_SPACE);
2223     if (!allocation.To(&obj)) return false;
2224   }
2225   set_undefined_value(Oddball::cast(obj));
2226   Oddball::cast(obj)->set_kind(Oddball::kUndefined);
2227   DCHECK(!InNewSpace(undefined_value()));
2228 
2229   // Set preliminary exception sentinel value before actually initializing it.
2230   set_exception(null_value());
2231 
2232   // Allocate the empty descriptor array.
2233   {
2234     AllocationResult allocation = AllocateEmptyFixedArray();
2235     if (!allocation.To(&obj)) return false;
2236   }
2237   set_empty_descriptor_array(DescriptorArray::cast(obj));
2238 
2239   // Fix the instance_descriptors for the existing maps.
2240   meta_map()->set_code_cache(empty_fixed_array());
2241   meta_map()->set_dependent_code(DependentCode::cast(empty_fixed_array()));
2242   meta_map()->set_raw_transitions(Smi::FromInt(0));
2243   meta_map()->set_instance_descriptors(empty_descriptor_array());
2244   if (FLAG_unbox_double_fields) {
2245     meta_map()->set_layout_descriptor(LayoutDescriptor::FastPointerLayout());
2246   }
2247 
2248   fixed_array_map()->set_code_cache(empty_fixed_array());
2249   fixed_array_map()->set_dependent_code(
2250       DependentCode::cast(empty_fixed_array()));
2251   fixed_array_map()->set_raw_transitions(Smi::FromInt(0));
2252   fixed_array_map()->set_instance_descriptors(empty_descriptor_array());
2253   if (FLAG_unbox_double_fields) {
2254     fixed_array_map()->set_layout_descriptor(
2255         LayoutDescriptor::FastPointerLayout());
2256   }
2257 
2258   undefined_map()->set_code_cache(empty_fixed_array());
2259   undefined_map()->set_dependent_code(DependentCode::cast(empty_fixed_array()));
2260   undefined_map()->set_raw_transitions(Smi::FromInt(0));
2261   undefined_map()->set_instance_descriptors(empty_descriptor_array());
2262   if (FLAG_unbox_double_fields) {
2263     undefined_map()->set_layout_descriptor(
2264         LayoutDescriptor::FastPointerLayout());
2265   }
2266 
2267   null_map()->set_code_cache(empty_fixed_array());
2268   null_map()->set_dependent_code(DependentCode::cast(empty_fixed_array()));
2269   null_map()->set_raw_transitions(Smi::FromInt(0));
2270   null_map()->set_instance_descriptors(empty_descriptor_array());
2271   if (FLAG_unbox_double_fields) {
2272     null_map()->set_layout_descriptor(LayoutDescriptor::FastPointerLayout());
2273   }
2274 
2275   // Fix prototype object for existing maps.
2276   meta_map()->set_prototype(null_value());
2277   meta_map()->set_constructor_or_backpointer(null_value());
2278 
2279   fixed_array_map()->set_prototype(null_value());
2280   fixed_array_map()->set_constructor_or_backpointer(null_value());
2281 
2282   undefined_map()->set_prototype(null_value());
2283   undefined_map()->set_constructor_or_backpointer(null_value());
2284 
2285   null_map()->set_prototype(null_value());
2286   null_map()->set_constructor_or_backpointer(null_value());
2287 
2288   {  // Map allocation
2289 #define ALLOCATE_MAP(instance_type, size, field_name)               \
2290   {                                                                 \
2291     Map* map;                                                       \
2292     if (!AllocateMap((instance_type), size).To(&map)) return false; \
2293     set_##field_name##_map(map);                                    \
2294   }
2295 
2296 #define ALLOCATE_VARSIZE_MAP(instance_type, field_name) \
2297   ALLOCATE_MAP(instance_type, kVariableSizeSentinel, field_name)
2298 
2299 #define ALLOCATE_PRIMITIVE_MAP(instance_type, size, field_name, \
2300                                constructor_function_index)      \
2301   {                                                             \
2302     ALLOCATE_MAP((instance_type), (size), field_name);          \
2303     field_name##_map()->SetConstructorFunctionIndex(            \
2304         (constructor_function_index));                          \
2305   }
2306 
2307     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, fixed_cow_array)
2308     DCHECK(fixed_array_map() != fixed_cow_array_map());
2309 
2310     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, scope_info)
2311     ALLOCATE_PRIMITIVE_MAP(HEAP_NUMBER_TYPE, HeapNumber::kSize, heap_number,
2312                            Context::NUMBER_FUNCTION_INDEX)
2313     ALLOCATE_MAP(MUTABLE_HEAP_NUMBER_TYPE, HeapNumber::kSize,
2314                  mutable_heap_number)
2315     ALLOCATE_PRIMITIVE_MAP(SYMBOL_TYPE, Symbol::kSize, symbol,
2316                            Context::SYMBOL_FUNCTION_INDEX)
2317 #define ALLOCATE_SIMD128_MAP(TYPE, Type, type, lane_count, lane_type) \
2318   ALLOCATE_PRIMITIVE_MAP(SIMD128_VALUE_TYPE, Type::kSize, type,       \
2319                          Context::TYPE##_FUNCTION_INDEX)
2320     SIMD128_TYPES(ALLOCATE_SIMD128_MAP)
2321 #undef ALLOCATE_SIMD128_MAP
2322     ALLOCATE_MAP(FOREIGN_TYPE, Foreign::kSize, foreign)
2323 
2324     ALLOCATE_MAP(ODDBALL_TYPE, Oddball::kSize, the_hole);
2325     ALLOCATE_PRIMITIVE_MAP(ODDBALL_TYPE, Oddball::kSize, boolean,
2326                            Context::BOOLEAN_FUNCTION_INDEX);
2327     ALLOCATE_MAP(ODDBALL_TYPE, Oddball::kSize, uninitialized);
2328     ALLOCATE_MAP(ODDBALL_TYPE, Oddball::kSize, arguments_marker);
2329     ALLOCATE_MAP(ODDBALL_TYPE, Oddball::kSize, no_interceptor_result_sentinel);
2330     ALLOCATE_MAP(ODDBALL_TYPE, Oddball::kSize, exception);
2331     ALLOCATE_MAP(ODDBALL_TYPE, Oddball::kSize, termination_exception);
2332 
2333     for (unsigned i = 0; i < arraysize(string_type_table); i++) {
2334       const StringTypeTable& entry = string_type_table[i];
2335       {
2336         AllocationResult allocation = AllocateMap(entry.type, entry.size);
2337         if (!allocation.To(&obj)) return false;
2338       }
2339       Map* map = Map::cast(obj);
2340       map->SetConstructorFunctionIndex(Context::STRING_FUNCTION_INDEX);
2341       // Mark cons string maps as unstable, because their objects can change
2342       // maps during GC.
2343       if (StringShape(entry.type).IsCons()) map->mark_unstable();
2344       roots_[entry.index] = map;
2345     }
2346 
2347     {  // Create a separate external one byte string map for native sources.
2348       AllocationResult allocation = AllocateMap(EXTERNAL_ONE_BYTE_STRING_TYPE,
2349                                                 ExternalOneByteString::kSize);
2350       if (!allocation.To(&obj)) return false;
2351       Map* map = Map::cast(obj);
2352       map->SetConstructorFunctionIndex(Context::STRING_FUNCTION_INDEX);
2353       set_native_source_string_map(map);
2354     }
2355 
2356     ALLOCATE_VARSIZE_MAP(FIXED_DOUBLE_ARRAY_TYPE, fixed_double_array)
2357     ALLOCATE_VARSIZE_MAP(BYTE_ARRAY_TYPE, byte_array)
2358     ALLOCATE_VARSIZE_MAP(BYTECODE_ARRAY_TYPE, bytecode_array)
2359     ALLOCATE_VARSIZE_MAP(FREE_SPACE_TYPE, free_space)
2360 
2361 #define ALLOCATE_FIXED_TYPED_ARRAY_MAP(Type, type, TYPE, ctype, size) \
2362   ALLOCATE_VARSIZE_MAP(FIXED_##TYPE##_ARRAY_TYPE, fixed_##type##_array)
2363 
2364     TYPED_ARRAYS(ALLOCATE_FIXED_TYPED_ARRAY_MAP)
2365 #undef ALLOCATE_FIXED_TYPED_ARRAY_MAP
2366 
2367     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, sloppy_arguments_elements)
2368 
2369     ALLOCATE_VARSIZE_MAP(CODE_TYPE, code)
2370 
2371     ALLOCATE_MAP(CELL_TYPE, Cell::kSize, cell)
2372     ALLOCATE_MAP(PROPERTY_CELL_TYPE, PropertyCell::kSize, global_property_cell)
2373     ALLOCATE_MAP(WEAK_CELL_TYPE, WeakCell::kSize, weak_cell)
2374     ALLOCATE_MAP(FILLER_TYPE, kPointerSize, one_pointer_filler)
2375     ALLOCATE_MAP(FILLER_TYPE, 2 * kPointerSize, two_pointer_filler)
2376 
2377     ALLOCATE_VARSIZE_MAP(TRANSITION_ARRAY_TYPE, transition_array)
2378 
2379     for (unsigned i = 0; i < arraysize(struct_table); i++) {
2380       const StructTable& entry = struct_table[i];
2381       Map* map;
2382       if (!AllocateMap(entry.type, entry.size).To(&map)) return false;
2383       roots_[entry.index] = map;
2384     }
2385 
2386     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, hash_table)
2387     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, ordered_hash_table)
2388 
2389     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, function_context)
2390     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, catch_context)
2391     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, with_context)
2392     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, block_context)
2393     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, module_context)
2394     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, script_context)
2395     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, script_context_table)
2396 
2397     ALLOCATE_VARSIZE_MAP(FIXED_ARRAY_TYPE, native_context)
2398     native_context_map()->set_dictionary_map(true);
2399     native_context_map()->set_visitor_id(
2400         StaticVisitorBase::kVisitNativeContext);
2401 
2402     ALLOCATE_MAP(SHARED_FUNCTION_INFO_TYPE, SharedFunctionInfo::kAlignedSize,
2403                  shared_function_info)
2404 
2405     ALLOCATE_MAP(JS_MESSAGE_OBJECT_TYPE, JSMessageObject::kSize, message_object)
2406     ALLOCATE_MAP(JS_OBJECT_TYPE, JSObject::kHeaderSize + kPointerSize, external)
2407     external_map()->set_is_extensible(false);
2408 #undef ALLOCATE_PRIMITIVE_MAP
2409 #undef ALLOCATE_VARSIZE_MAP
2410 #undef ALLOCATE_MAP
2411   }
2412 
2413   {  // Empty arrays
2414     {
2415       ByteArray* byte_array;
2416       if (!AllocateByteArray(0, TENURED).To(&byte_array)) return false;
2417       set_empty_byte_array(byte_array);
2418 
2419       BytecodeArray* bytecode_array = nullptr;
2420       AllocationResult allocation =
2421           AllocateBytecodeArray(0, nullptr, 0, 0, empty_fixed_array());
2422       if (!allocation.To(&bytecode_array)) {
2423         return false;
2424       }
2425       set_empty_bytecode_array(bytecode_array);
2426     }
2427 
2428 #define ALLOCATE_EMPTY_FIXED_TYPED_ARRAY(Type, type, TYPE, ctype, size) \
2429   {                                                                     \
2430     FixedTypedArrayBase* obj;                                           \
2431     if (!AllocateEmptyFixedTypedArray(kExternal##Type##Array).To(&obj)) \
2432       return false;                                                     \
2433     set_empty_fixed_##type##_array(obj);                                \
2434   }
2435 
2436     TYPED_ARRAYS(ALLOCATE_EMPTY_FIXED_TYPED_ARRAY)
2437 #undef ALLOCATE_EMPTY_FIXED_TYPED_ARRAY
2438   }
2439   DCHECK(!InNewSpace(empty_fixed_array()));
2440   return true;
2441 }
2442 
2443 
AllocateHeapNumber(double value,MutableMode mode,PretenureFlag pretenure)2444 AllocationResult Heap::AllocateHeapNumber(double value, MutableMode mode,
2445                                           PretenureFlag pretenure) {
2446   // Statically ensure that it is safe to allocate heap numbers in paged
2447   // spaces.
2448   int size = HeapNumber::kSize;
2449   STATIC_ASSERT(HeapNumber::kSize <= Page::kMaxRegularHeapObjectSize);
2450 
2451   AllocationSpace space = SelectSpace(pretenure);
2452 
2453   HeapObject* result = nullptr;
2454   {
2455     AllocationResult allocation = AllocateRaw(size, space, kDoubleUnaligned);
2456     if (!allocation.To(&result)) return allocation;
2457   }
2458 
2459   Map* map = mode == MUTABLE ? mutable_heap_number_map() : heap_number_map();
2460   HeapObject::cast(result)->set_map_no_write_barrier(map);
2461   HeapNumber::cast(result)->set_value(value);
2462   return result;
2463 }
2464 
2465 #define SIMD_ALLOCATE_DEFINITION(TYPE, Type, type, lane_count, lane_type) \
2466   AllocationResult Heap::Allocate##Type(lane_type lanes[lane_count],      \
2467                                         PretenureFlag pretenure) {        \
2468     int size = Type::kSize;                                               \
2469     STATIC_ASSERT(Type::kSize <= Page::kMaxRegularHeapObjectSize);        \
2470                                                                           \
2471     AllocationSpace space = SelectSpace(pretenure);                       \
2472                                                                           \
2473     HeapObject* result = nullptr;                                         \
2474     {                                                                     \
2475       AllocationResult allocation =                                       \
2476           AllocateRaw(size, space, kSimd128Unaligned);                    \
2477       if (!allocation.To(&result)) return allocation;                     \
2478     }                                                                     \
2479                                                                           \
2480     result->set_map_no_write_barrier(type##_map());                       \
2481     Type* instance = Type::cast(result);                                  \
2482     for (int i = 0; i < lane_count; i++) {                                \
2483       instance->set_lane(i, lanes[i]);                                    \
2484     }                                                                     \
2485     return result;                                                        \
2486   }
SIMD128_TYPES(SIMD_ALLOCATE_DEFINITION)2487 SIMD128_TYPES(SIMD_ALLOCATE_DEFINITION)
2488 #undef SIMD_ALLOCATE_DEFINITION
2489 
2490 
2491 AllocationResult Heap::AllocateCell(Object* value) {
2492   int size = Cell::kSize;
2493   STATIC_ASSERT(Cell::kSize <= Page::kMaxRegularHeapObjectSize);
2494 
2495   HeapObject* result = nullptr;
2496   {
2497     AllocationResult allocation = AllocateRaw(size, OLD_SPACE);
2498     if (!allocation.To(&result)) return allocation;
2499   }
2500   result->set_map_no_write_barrier(cell_map());
2501   Cell::cast(result)->set_value(value);
2502   return result;
2503 }
2504 
2505 
AllocatePropertyCell()2506 AllocationResult Heap::AllocatePropertyCell() {
2507   int size = PropertyCell::kSize;
2508   STATIC_ASSERT(PropertyCell::kSize <= Page::kMaxRegularHeapObjectSize);
2509 
2510   HeapObject* result = nullptr;
2511   AllocationResult allocation = AllocateRaw(size, OLD_SPACE);
2512   if (!allocation.To(&result)) return allocation;
2513 
2514   result->set_map_no_write_barrier(global_property_cell_map());
2515   PropertyCell* cell = PropertyCell::cast(result);
2516   cell->set_dependent_code(DependentCode::cast(empty_fixed_array()),
2517                            SKIP_WRITE_BARRIER);
2518   cell->set_property_details(PropertyDetails(Smi::FromInt(0)));
2519   cell->set_value(the_hole_value());
2520   return result;
2521 }
2522 
2523 
AllocateWeakCell(HeapObject * value)2524 AllocationResult Heap::AllocateWeakCell(HeapObject* value) {
2525   int size = WeakCell::kSize;
2526   STATIC_ASSERT(WeakCell::kSize <= Page::kMaxRegularHeapObjectSize);
2527   HeapObject* result = nullptr;
2528   {
2529     AllocationResult allocation = AllocateRaw(size, OLD_SPACE);
2530     if (!allocation.To(&result)) return allocation;
2531   }
2532   result->set_map_no_write_barrier(weak_cell_map());
2533   WeakCell::cast(result)->initialize(value);
2534   WeakCell::cast(result)->clear_next(the_hole_value());
2535   return result;
2536 }
2537 
2538 
AllocateTransitionArray(int capacity)2539 AllocationResult Heap::AllocateTransitionArray(int capacity) {
2540   DCHECK(capacity > 0);
2541   HeapObject* raw_array = nullptr;
2542   {
2543     AllocationResult allocation = AllocateRawFixedArray(capacity, TENURED);
2544     if (!allocation.To(&raw_array)) return allocation;
2545   }
2546   raw_array->set_map_no_write_barrier(transition_array_map());
2547   TransitionArray* array = TransitionArray::cast(raw_array);
2548   array->set_length(capacity);
2549   MemsetPointer(array->data_start(), undefined_value(), capacity);
2550   return array;
2551 }
2552 
2553 
CreateApiObjects()2554 void Heap::CreateApiObjects() {
2555   HandleScope scope(isolate());
2556   Factory* factory = isolate()->factory();
2557   Handle<Map> new_neander_map =
2558       factory->NewMap(JS_OBJECT_TYPE, JSObject::kHeaderSize);
2559 
2560   // Don't use Smi-only elements optimizations for objects with the neander
2561   // map. There are too many cases where element values are set directly with a
2562   // bottleneck to trap the Smi-only -> fast elements transition, and there
2563   // appears to be no benefit for optimize this case.
2564   new_neander_map->set_elements_kind(TERMINAL_FAST_ELEMENTS_KIND);
2565   set_neander_map(*new_neander_map);
2566 
2567   Handle<JSObject> listeners = factory->NewNeanderObject();
2568   Handle<FixedArray> elements = factory->NewFixedArray(2);
2569   elements->set(0, Smi::FromInt(0));
2570   listeners->set_elements(*elements);
2571   set_message_listeners(*listeners);
2572 }
2573 
2574 
CreateJSEntryStub()2575 void Heap::CreateJSEntryStub() {
2576   JSEntryStub stub(isolate(), StackFrame::ENTRY);
2577   set_js_entry_code(*stub.GetCode());
2578 }
2579 
2580 
CreateJSConstructEntryStub()2581 void Heap::CreateJSConstructEntryStub() {
2582   JSEntryStub stub(isolate(), StackFrame::ENTRY_CONSTRUCT);
2583   set_js_construct_entry_code(*stub.GetCode());
2584 }
2585 
2586 
CreateFixedStubs()2587 void Heap::CreateFixedStubs() {
2588   // Here we create roots for fixed stubs. They are needed at GC
2589   // for cooking and uncooking (check out frames.cc).
2590   // The eliminates the need for doing dictionary lookup in the
2591   // stub cache for these stubs.
2592   HandleScope scope(isolate());
2593 
2594   // Create stubs that should be there, so we don't unexpectedly have to
2595   // create them if we need them during the creation of another stub.
2596   // Stub creation mixes raw pointers and handles in an unsafe manner so
2597   // we cannot create stubs while we are creating stubs.
2598   CodeStub::GenerateStubsAheadOfTime(isolate());
2599 
2600   // MacroAssembler::Abort calls (usually enabled with --debug-code) depend on
2601   // CEntryStub, so we need to call GenerateStubsAheadOfTime before JSEntryStub
2602   // is created.
2603 
2604   // gcc-4.4 has problem generating correct code of following snippet:
2605   // {  JSEntryStub stub;
2606   //    js_entry_code_ = *stub.GetCode();
2607   // }
2608   // {  JSConstructEntryStub stub;
2609   //    js_construct_entry_code_ = *stub.GetCode();
2610   // }
2611   // To workaround the problem, make separate functions without inlining.
2612   Heap::CreateJSEntryStub();
2613   Heap::CreateJSConstructEntryStub();
2614 }
2615 
2616 
CreateInitialObjects()2617 void Heap::CreateInitialObjects() {
2618   HandleScope scope(isolate());
2619   Factory* factory = isolate()->factory();
2620 
2621   // The -0 value must be set before NewNumber works.
2622   set_minus_zero_value(*factory->NewHeapNumber(-0.0, IMMUTABLE, TENURED));
2623   DCHECK(std::signbit(minus_zero_value()->Number()) != 0);
2624 
2625   set_nan_value(*factory->NewHeapNumber(
2626       std::numeric_limits<double>::quiet_NaN(), IMMUTABLE, TENURED));
2627   set_infinity_value(*factory->NewHeapNumber(V8_INFINITY, IMMUTABLE, TENURED));
2628   set_minus_infinity_value(
2629       *factory->NewHeapNumber(-V8_INFINITY, IMMUTABLE, TENURED));
2630 
2631   // The hole has not been created yet, but we want to put something
2632   // predictable in the gaps in the string table, so lets make that Smi zero.
2633   set_the_hole_value(reinterpret_cast<Oddball*>(Smi::FromInt(0)));
2634 
2635   // Allocate initial string table.
2636   set_string_table(*StringTable::New(isolate(), kInitialStringTableSize));
2637 
2638   // Finish initializing oddballs after creating the string table.
2639   Oddball::Initialize(isolate(), factory->undefined_value(), "undefined",
2640                       factory->nan_value(), "undefined", Oddball::kUndefined);
2641 
2642   // Initialize the null_value.
2643   Oddball::Initialize(isolate(), factory->null_value(), "null",
2644                       handle(Smi::FromInt(0), isolate()), "object",
2645                       Oddball::kNull);
2646 
2647   set_true_value(*factory->NewOddball(factory->boolean_map(), "true",
2648                                       handle(Smi::FromInt(1), isolate()),
2649                                       "boolean", Oddball::kTrue));
2650 
2651   set_false_value(*factory->NewOddball(factory->boolean_map(), "false",
2652                                        handle(Smi::FromInt(0), isolate()),
2653                                        "boolean", Oddball::kFalse));
2654 
2655   set_the_hole_value(*factory->NewOddball(factory->the_hole_map(), "hole",
2656                                           handle(Smi::FromInt(-1), isolate()),
2657                                           "undefined", Oddball::kTheHole));
2658 
2659   set_uninitialized_value(
2660       *factory->NewOddball(factory->uninitialized_map(), "uninitialized",
2661                            handle(Smi::FromInt(-1), isolate()), "undefined",
2662                            Oddball::kUninitialized));
2663 
2664   set_arguments_marker(
2665       *factory->NewOddball(factory->arguments_marker_map(), "arguments_marker",
2666                            handle(Smi::FromInt(-4), isolate()), "undefined",
2667                            Oddball::kArgumentMarker));
2668 
2669   set_no_interceptor_result_sentinel(*factory->NewOddball(
2670       factory->no_interceptor_result_sentinel_map(),
2671       "no_interceptor_result_sentinel", handle(Smi::FromInt(-2), isolate()),
2672       "undefined", Oddball::kOther));
2673 
2674   set_termination_exception(*factory->NewOddball(
2675       factory->termination_exception_map(), "termination_exception",
2676       handle(Smi::FromInt(-3), isolate()), "undefined", Oddball::kOther));
2677 
2678   set_exception(*factory->NewOddball(factory->exception_map(), "exception",
2679                                      handle(Smi::FromInt(-5), isolate()),
2680                                      "undefined", Oddball::kException));
2681 
2682   for (unsigned i = 0; i < arraysize(constant_string_table); i++) {
2683     Handle<String> str =
2684         factory->InternalizeUtf8String(constant_string_table[i].contents);
2685     roots_[constant_string_table[i].index] = *str;
2686   }
2687 
2688   // The {hidden_string} is special because it is an empty string, but does not
2689   // match any string (even the {empty_string}) when looked up in properties.
2690   // Allocate the hidden string which is used to identify the hidden properties
2691   // in JSObjects. The hash code has a special value so that it will not match
2692   // the empty string when searching for the property. It cannot be part of the
2693   // loop above because it needs to be allocated manually with the special
2694   // hash code in place. The hash code for the hidden_string is zero to ensure
2695   // that it will always be at the first entry in property descriptors.
2696   set_hidden_string(*factory->NewOneByteInternalizedString(
2697       OneByteVector("", 0), String::kEmptyStringHash));
2698 
2699   // Create the code_stubs dictionary. The initial size is set to avoid
2700   // expanding the dictionary during bootstrapping.
2701   set_code_stubs(*UnseededNumberDictionary::New(isolate(), 128));
2702 
2703   // Create the non_monomorphic_cache used in stub-cache.cc. The initial size
2704   // is set to avoid expanding the dictionary during bootstrapping.
2705   set_non_monomorphic_cache(*UnseededNumberDictionary::New(isolate(), 64));
2706 
2707   set_polymorphic_code_cache(PolymorphicCodeCache::cast(
2708       *factory->NewStruct(POLYMORPHIC_CODE_CACHE_TYPE)));
2709 
2710   set_instanceof_cache_function(Smi::FromInt(0));
2711   set_instanceof_cache_map(Smi::FromInt(0));
2712   set_instanceof_cache_answer(Smi::FromInt(0));
2713 
2714   {
2715     HandleScope scope(isolate());
2716 #define SYMBOL_INIT(name)                                              \
2717   {                                                                    \
2718     Handle<String> name##d = factory->NewStringFromStaticChars(#name); \
2719     Handle<Symbol> symbol(isolate()->factory()->NewPrivateSymbol());   \
2720     symbol->set_name(*name##d);                                        \
2721     roots_[k##name##RootIndex] = *symbol;                              \
2722   }
2723     PRIVATE_SYMBOL_LIST(SYMBOL_INIT)
2724 #undef SYMBOL_INIT
2725   }
2726 
2727   {
2728     HandleScope scope(isolate());
2729 #define SYMBOL_INIT(name, description)                                      \
2730   Handle<Symbol> name = factory->NewSymbol();                               \
2731   Handle<String> name##d = factory->NewStringFromStaticChars(#description); \
2732   name->set_name(*name##d);                                                 \
2733   roots_[k##name##RootIndex] = *name;
2734     PUBLIC_SYMBOL_LIST(SYMBOL_INIT)
2735 #undef SYMBOL_INIT
2736 
2737 #define SYMBOL_INIT(name, description)                                      \
2738   Handle<Symbol> name = factory->NewSymbol();                               \
2739   Handle<String> name##d = factory->NewStringFromStaticChars(#description); \
2740   name->set_is_well_known_symbol(true);                                     \
2741   name->set_name(*name##d);                                                 \
2742   roots_[k##name##RootIndex] = *name;
2743     WELL_KNOWN_SYMBOL_LIST(SYMBOL_INIT)
2744 #undef SYMBOL_INIT
2745   }
2746 
2747   CreateFixedStubs();
2748 
2749   // Allocate the dictionary of intrinsic function names.
2750   Handle<NameDictionary> intrinsic_names =
2751       NameDictionary::New(isolate(), Runtime::kNumFunctions, TENURED);
2752   Runtime::InitializeIntrinsicFunctionNames(isolate(), intrinsic_names);
2753   set_intrinsic_function_names(*intrinsic_names);
2754 
2755   Handle<NameDictionary> empty_properties_dictionary =
2756       NameDictionary::New(isolate(), 0, TENURED);
2757   empty_properties_dictionary->SetRequiresCopyOnCapacityChange();
2758   set_empty_properties_dictionary(*empty_properties_dictionary);
2759 
2760   set_number_string_cache(
2761       *factory->NewFixedArray(kInitialNumberStringCacheSize * 2, TENURED));
2762 
2763   // Allocate cache for single character one byte strings.
2764   set_single_character_string_cache(
2765       *factory->NewFixedArray(String::kMaxOneByteCharCode + 1, TENURED));
2766 
2767   // Allocate cache for string split and regexp-multiple.
2768   set_string_split_cache(*factory->NewFixedArray(
2769       RegExpResultsCache::kRegExpResultsCacheSize, TENURED));
2770   set_regexp_multiple_cache(*factory->NewFixedArray(
2771       RegExpResultsCache::kRegExpResultsCacheSize, TENURED));
2772 
2773   // Allocate cache for external strings pointing to native source code.
2774   set_natives_source_cache(
2775       *factory->NewFixedArray(Natives::GetBuiltinsCount()));
2776 
2777   set_experimental_natives_source_cache(
2778       *factory->NewFixedArray(ExperimentalNatives::GetBuiltinsCount()));
2779 
2780   set_extra_natives_source_cache(
2781       *factory->NewFixedArray(ExtraNatives::GetBuiltinsCount()));
2782 
2783   set_experimental_extra_natives_source_cache(
2784       *factory->NewFixedArray(ExperimentalExtraNatives::GetBuiltinsCount()));
2785 
2786   set_undefined_cell(*factory->NewCell(factory->undefined_value()));
2787 
2788   // The symbol registry is initialized lazily.
2789   set_symbol_registry(Smi::FromInt(0));
2790 
2791   // Allocate object to hold object observation state.
2792   set_observation_state(*factory->NewJSObjectFromMap(
2793       factory->NewMap(JS_OBJECT_TYPE, JSObject::kHeaderSize)));
2794 
2795   // Microtask queue uses the empty fixed array as a sentinel for "empty".
2796   // Number of queued microtasks stored in Isolate::pending_microtask_count().
2797   set_microtask_queue(empty_fixed_array());
2798 
2799   {
2800     StaticFeedbackVectorSpec spec;
2801     FeedbackVectorSlot load_ic_slot = spec.AddLoadICSlot();
2802     FeedbackVectorSlot keyed_load_ic_slot = spec.AddKeyedLoadICSlot();
2803     FeedbackVectorSlot store_ic_slot = spec.AddStoreICSlot();
2804     FeedbackVectorSlot keyed_store_ic_slot = spec.AddKeyedStoreICSlot();
2805 
2806     DCHECK_EQ(load_ic_slot,
2807               FeedbackVectorSlot(TypeFeedbackVector::kDummyLoadICSlot));
2808     DCHECK_EQ(keyed_load_ic_slot,
2809               FeedbackVectorSlot(TypeFeedbackVector::kDummyKeyedLoadICSlot));
2810     DCHECK_EQ(store_ic_slot,
2811               FeedbackVectorSlot(TypeFeedbackVector::kDummyStoreICSlot));
2812     DCHECK_EQ(keyed_store_ic_slot,
2813               FeedbackVectorSlot(TypeFeedbackVector::kDummyKeyedStoreICSlot));
2814 
2815     Handle<TypeFeedbackMetadata> dummy_metadata =
2816         TypeFeedbackMetadata::New(isolate(), &spec);
2817     Handle<TypeFeedbackVector> dummy_vector =
2818         TypeFeedbackVector::New(isolate(), dummy_metadata);
2819 
2820     Object* megamorphic = *TypeFeedbackVector::MegamorphicSentinel(isolate());
2821     dummy_vector->Set(load_ic_slot, megamorphic, SKIP_WRITE_BARRIER);
2822     dummy_vector->Set(keyed_load_ic_slot, megamorphic, SKIP_WRITE_BARRIER);
2823     dummy_vector->Set(store_ic_slot, megamorphic, SKIP_WRITE_BARRIER);
2824     dummy_vector->Set(keyed_store_ic_slot, megamorphic, SKIP_WRITE_BARRIER);
2825 
2826     set_dummy_vector(*dummy_vector);
2827   }
2828 
2829   {
2830     Handle<WeakCell> cell = factory->NewWeakCell(factory->undefined_value());
2831     set_empty_weak_cell(*cell);
2832     cell->clear();
2833 
2834     Handle<FixedArray> cleared_optimized_code_map =
2835         factory->NewFixedArray(SharedFunctionInfo::kEntriesStart, TENURED);
2836     cleared_optimized_code_map->set(SharedFunctionInfo::kSharedCodeIndex,
2837                                     *cell);
2838     STATIC_ASSERT(SharedFunctionInfo::kEntriesStart == 1 &&
2839                   SharedFunctionInfo::kSharedCodeIndex == 0);
2840     set_cleared_optimized_code_map(*cleared_optimized_code_map);
2841   }
2842 
2843   set_detached_contexts(empty_fixed_array());
2844   set_retained_maps(ArrayList::cast(empty_fixed_array()));
2845 
2846   set_weak_object_to_code_table(
2847       *WeakHashTable::New(isolate(), 16, USE_DEFAULT_MINIMUM_CAPACITY,
2848                           TENURED));
2849 
2850   set_script_list(Smi::FromInt(0));
2851 
2852   Handle<SeededNumberDictionary> slow_element_dictionary =
2853       SeededNumberDictionary::New(isolate(), 0, TENURED);
2854   slow_element_dictionary->set_requires_slow_elements();
2855   set_empty_slow_element_dictionary(*slow_element_dictionary);
2856 
2857   set_materialized_objects(*factory->NewFixedArray(0, TENURED));
2858 
2859   // Handling of script id generation is in Heap::NextScriptId().
2860   set_last_script_id(Smi::FromInt(v8::UnboundScript::kNoScriptId));
2861 
2862   // Allocate the empty script.
2863   Handle<Script> script = factory->NewScript(factory->empty_string());
2864   script->set_type(Script::TYPE_NATIVE);
2865   set_empty_script(*script);
2866 
2867   Handle<PropertyCell> cell = factory->NewPropertyCell();
2868   cell->set_value(Smi::FromInt(Isolate::kArrayProtectorValid));
2869   set_array_protector(*cell);
2870 
2871   cell = factory->NewPropertyCell();
2872   cell->set_value(the_hole_value());
2873   set_empty_property_cell(*cell);
2874 
2875   set_weak_stack_trace_list(Smi::FromInt(0));
2876 
2877   set_noscript_shared_function_infos(Smi::FromInt(0));
2878 
2879   // Will be filled in by Interpreter::Initialize().
2880   set_interpreter_table(
2881       *interpreter::Interpreter::CreateUninitializedInterpreterTable(
2882           isolate()));
2883 
2884   // Initialize keyed lookup cache.
2885   isolate_->keyed_lookup_cache()->Clear();
2886 
2887   // Initialize context slot cache.
2888   isolate_->context_slot_cache()->Clear();
2889 
2890   // Initialize descriptor cache.
2891   isolate_->descriptor_lookup_cache()->Clear();
2892 
2893   // Initialize compilation cache.
2894   isolate_->compilation_cache()->Clear();
2895 }
2896 
2897 
RootCanBeWrittenAfterInitialization(Heap::RootListIndex root_index)2898 bool Heap::RootCanBeWrittenAfterInitialization(Heap::RootListIndex root_index) {
2899   switch (root_index) {
2900     case kStoreBufferTopRootIndex:
2901     case kNumberStringCacheRootIndex:
2902     case kInstanceofCacheFunctionRootIndex:
2903     case kInstanceofCacheMapRootIndex:
2904     case kInstanceofCacheAnswerRootIndex:
2905     case kCodeStubsRootIndex:
2906     case kNonMonomorphicCacheRootIndex:
2907     case kPolymorphicCodeCacheRootIndex:
2908     case kEmptyScriptRootIndex:
2909     case kSymbolRegistryRootIndex:
2910     case kScriptListRootIndex:
2911     case kMaterializedObjectsRootIndex:
2912     case kMicrotaskQueueRootIndex:
2913     case kDetachedContextsRootIndex:
2914     case kWeakObjectToCodeTableRootIndex:
2915     case kRetainedMapsRootIndex:
2916     case kNoScriptSharedFunctionInfosRootIndex:
2917     case kWeakStackTraceListRootIndex:
2918 // Smi values
2919 #define SMI_ENTRY(type, name, Name) case k##Name##RootIndex:
2920       SMI_ROOT_LIST(SMI_ENTRY)
2921 #undef SMI_ENTRY
2922     // String table
2923     case kStringTableRootIndex:
2924       return true;
2925 
2926     default:
2927       return false;
2928   }
2929 }
2930 
2931 
RootCanBeTreatedAsConstant(RootListIndex root_index)2932 bool Heap::RootCanBeTreatedAsConstant(RootListIndex root_index) {
2933   return !RootCanBeWrittenAfterInitialization(root_index) &&
2934          !InNewSpace(root(root_index));
2935 }
2936 
2937 
FullSizeNumberStringCacheLength()2938 int Heap::FullSizeNumberStringCacheLength() {
2939   // Compute the size of the number string cache based on the max newspace size.
2940   // The number string cache has a minimum size based on twice the initial cache
2941   // size to ensure that it is bigger after being made 'full size'.
2942   int number_string_cache_size = max_semi_space_size_ / 512;
2943   number_string_cache_size = Max(kInitialNumberStringCacheSize * 2,
2944                                  Min(0x4000, number_string_cache_size));
2945   // There is a string and a number per entry so the length is twice the number
2946   // of entries.
2947   return number_string_cache_size * 2;
2948 }
2949 
2950 
FlushNumberStringCache()2951 void Heap::FlushNumberStringCache() {
2952   // Flush the number to string cache.
2953   int len = number_string_cache()->length();
2954   for (int i = 0; i < len; i++) {
2955     number_string_cache()->set_undefined(i);
2956   }
2957 }
2958 
2959 
MapForFixedTypedArray(ExternalArrayType array_type)2960 Map* Heap::MapForFixedTypedArray(ExternalArrayType array_type) {
2961   return Map::cast(roots_[RootIndexForFixedTypedArray(array_type)]);
2962 }
2963 
2964 
RootIndexForFixedTypedArray(ExternalArrayType array_type)2965 Heap::RootListIndex Heap::RootIndexForFixedTypedArray(
2966     ExternalArrayType array_type) {
2967   switch (array_type) {
2968 #define ARRAY_TYPE_TO_ROOT_INDEX(Type, type, TYPE, ctype, size) \
2969   case kExternal##Type##Array:                                  \
2970     return kFixed##Type##ArrayMapRootIndex;
2971 
2972     TYPED_ARRAYS(ARRAY_TYPE_TO_ROOT_INDEX)
2973 #undef ARRAY_TYPE_TO_ROOT_INDEX
2974 
2975     default:
2976       UNREACHABLE();
2977       return kUndefinedValueRootIndex;
2978   }
2979 }
2980 
2981 
RootIndexForEmptyFixedTypedArray(ElementsKind elementsKind)2982 Heap::RootListIndex Heap::RootIndexForEmptyFixedTypedArray(
2983     ElementsKind elementsKind) {
2984   switch (elementsKind) {
2985 #define ELEMENT_KIND_TO_ROOT_INDEX(Type, type, TYPE, ctype, size) \
2986   case TYPE##_ELEMENTS:                                           \
2987     return kEmptyFixed##Type##ArrayRootIndex;
2988 
2989     TYPED_ARRAYS(ELEMENT_KIND_TO_ROOT_INDEX)
2990 #undef ELEMENT_KIND_TO_ROOT_INDEX
2991     default:
2992       UNREACHABLE();
2993       return kUndefinedValueRootIndex;
2994   }
2995 }
2996 
2997 
EmptyFixedTypedArrayForMap(Map * map)2998 FixedTypedArrayBase* Heap::EmptyFixedTypedArrayForMap(Map* map) {
2999   return FixedTypedArrayBase::cast(
3000       roots_[RootIndexForEmptyFixedTypedArray(map->elements_kind())]);
3001 }
3002 
3003 
AllocateForeign(Address address,PretenureFlag pretenure)3004 AllocationResult Heap::AllocateForeign(Address address,
3005                                        PretenureFlag pretenure) {
3006   // Statically ensure that it is safe to allocate foreigns in paged spaces.
3007   STATIC_ASSERT(Foreign::kSize <= Page::kMaxRegularHeapObjectSize);
3008   AllocationSpace space = (pretenure == TENURED) ? OLD_SPACE : NEW_SPACE;
3009   Foreign* result = nullptr;
3010   AllocationResult allocation = Allocate(foreign_map(), space);
3011   if (!allocation.To(&result)) return allocation;
3012   result->set_foreign_address(address);
3013   return result;
3014 }
3015 
3016 
AllocateByteArray(int length,PretenureFlag pretenure)3017 AllocationResult Heap::AllocateByteArray(int length, PretenureFlag pretenure) {
3018   if (length < 0 || length > ByteArray::kMaxLength) {
3019     v8::internal::Heap::FatalProcessOutOfMemory("invalid array length", true);
3020   }
3021   int size = ByteArray::SizeFor(length);
3022   AllocationSpace space = SelectSpace(pretenure);
3023   HeapObject* result = nullptr;
3024   {
3025     AllocationResult allocation = AllocateRaw(size, space);
3026     if (!allocation.To(&result)) return allocation;
3027   }
3028 
3029   result->set_map_no_write_barrier(byte_array_map());
3030   ByteArray::cast(result)->set_length(length);
3031   return result;
3032 }
3033 
3034 
AllocateBytecodeArray(int length,const byte * const raw_bytecodes,int frame_size,int parameter_count,FixedArray * constant_pool)3035 AllocationResult Heap::AllocateBytecodeArray(int length,
3036                                              const byte* const raw_bytecodes,
3037                                              int frame_size,
3038                                              int parameter_count,
3039                                              FixedArray* constant_pool) {
3040   if (length < 0 || length > BytecodeArray::kMaxLength) {
3041     v8::internal::Heap::FatalProcessOutOfMemory("invalid array length", true);
3042   }
3043   // Bytecode array is pretenured, so constant pool array should be to.
3044   DCHECK(!InNewSpace(constant_pool));
3045 
3046   int size = BytecodeArray::SizeFor(length);
3047   HeapObject* result = nullptr;
3048   {
3049     AllocationResult allocation = AllocateRaw(size, OLD_SPACE);
3050     if (!allocation.To(&result)) return allocation;
3051   }
3052 
3053   result->set_map_no_write_barrier(bytecode_array_map());
3054   BytecodeArray* instance = BytecodeArray::cast(result);
3055   instance->set_length(length);
3056   instance->set_frame_size(frame_size);
3057   instance->set_parameter_count(parameter_count);
3058   instance->set_constant_pool(constant_pool);
3059   CopyBytes(instance->GetFirstBytecodeAddress(), raw_bytecodes, length);
3060 
3061   return result;
3062 }
3063 
3064 
CreateFillerObjectAt(Address addr,int size)3065 void Heap::CreateFillerObjectAt(Address addr, int size) {
3066   if (size == 0) return;
3067   HeapObject* filler = HeapObject::FromAddress(addr);
3068   if (size == kPointerSize) {
3069     filler->set_map_no_write_barrier(
3070         reinterpret_cast<Map*>(root(kOnePointerFillerMapRootIndex)));
3071   } else if (size == 2 * kPointerSize) {
3072     filler->set_map_no_write_barrier(
3073         reinterpret_cast<Map*>(root(kTwoPointerFillerMapRootIndex)));
3074   } else {
3075     DCHECK_GT(size, 2 * kPointerSize);
3076     filler->set_map_no_write_barrier(
3077         reinterpret_cast<Map*>(root(kFreeSpaceMapRootIndex)));
3078     FreeSpace::cast(filler)->nobarrier_set_size(size);
3079   }
3080   // At this point, we may be deserializing the heap from a snapshot, and
3081   // none of the maps have been created yet and are NULL.
3082   DCHECK((filler->map() == NULL && !deserialization_complete_) ||
3083          filler->map()->IsMap());
3084 }
3085 
3086 
CanMoveObjectStart(HeapObject * object)3087 bool Heap::CanMoveObjectStart(HeapObject* object) {
3088   if (!FLAG_move_object_start) return false;
3089 
3090   Address address = object->address();
3091 
3092   if (lo_space()->Contains(object)) return false;
3093 
3094   Page* page = Page::FromAddress(address);
3095   // We can move the object start if:
3096   // (1) the object is not in old space,
3097   // (2) the page of the object was already swept,
3098   // (3) the page was already concurrently swept. This case is an optimization
3099   // for concurrent sweeping. The WasSwept predicate for concurrently swept
3100   // pages is set after sweeping all pages.
3101   return !InOldSpace(address) || page->WasSwept() || page->SweepingCompleted();
3102 }
3103 
3104 
AdjustLiveBytes(HeapObject * object,int by,InvocationMode mode)3105 void Heap::AdjustLiveBytes(HeapObject* object, int by, InvocationMode mode) {
3106   // As long as the inspected object is black and we are currently not iterating
3107   // the heap using HeapIterator, we can update the live byte count. We cannot
3108   // update while using HeapIterator because the iterator is temporarily
3109   // marking the whole object graph, without updating live bytes.
3110   if (!in_heap_iterator() &&
3111       !mark_compact_collector()->sweeping_in_progress() &&
3112       Marking::IsBlack(Marking::MarkBitFrom(object->address()))) {
3113     if (mode == SEQUENTIAL_TO_SWEEPER) {
3114       MemoryChunk::IncrementLiveBytesFromGC(object, by);
3115     } else {
3116       MemoryChunk::IncrementLiveBytesFromMutator(object, by);
3117     }
3118   }
3119 }
3120 
3121 
LeftTrimFixedArray(FixedArrayBase * object,int elements_to_trim)3122 FixedArrayBase* Heap::LeftTrimFixedArray(FixedArrayBase* object,
3123                                          int elements_to_trim) {
3124   DCHECK(!object->IsFixedTypedArrayBase());
3125   DCHECK(!object->IsByteArray());
3126   const int element_size = object->IsFixedArray() ? kPointerSize : kDoubleSize;
3127   const int bytes_to_trim = elements_to_trim * element_size;
3128   Map* map = object->map();
3129 
3130   // For now this trick is only applied to objects in new and paged space.
3131   // In large object space the object's start must coincide with chunk
3132   // and thus the trick is just not applicable.
3133   DCHECK(!lo_space()->Contains(object));
3134   DCHECK(object->map() != fixed_cow_array_map());
3135 
3136   STATIC_ASSERT(FixedArrayBase::kMapOffset == 0);
3137   STATIC_ASSERT(FixedArrayBase::kLengthOffset == kPointerSize);
3138   STATIC_ASSERT(FixedArrayBase::kHeaderSize == 2 * kPointerSize);
3139 
3140   const int len = object->length();
3141   DCHECK(elements_to_trim <= len);
3142 
3143   // Calculate location of new array start.
3144   Address new_start = object->address() + bytes_to_trim;
3145 
3146   // Technically in new space this write might be omitted (except for
3147   // debug mode which iterates through the heap), but to play safer
3148   // we still do it.
3149   CreateFillerObjectAt(object->address(), bytes_to_trim);
3150 
3151   // Initialize header of the trimmed array. Since left trimming is only
3152   // performed on pages which are not concurrently swept creating a filler
3153   // object does not require synchronization.
3154   DCHECK(CanMoveObjectStart(object));
3155   Object** former_start = HeapObject::RawField(object, 0);
3156   int new_start_index = elements_to_trim * (element_size / kPointerSize);
3157   former_start[new_start_index] = map;
3158   former_start[new_start_index + 1] = Smi::FromInt(len - elements_to_trim);
3159   FixedArrayBase* new_object =
3160       FixedArrayBase::cast(HeapObject::FromAddress(new_start));
3161 
3162   // Maintain consistency of live bytes during incremental marking
3163   Marking::TransferMark(this, object->address(), new_start);
3164   AdjustLiveBytes(new_object, -bytes_to_trim, Heap::CONCURRENT_TO_SWEEPER);
3165 
3166   // Notify the heap profiler of change in object layout.
3167   OnMoveEvent(new_object, object, new_object->Size());
3168   return new_object;
3169 }
3170 
3171 
3172 // Force instantiation of templatized method.
3173 template void Heap::RightTrimFixedArray<Heap::SEQUENTIAL_TO_SWEEPER>(
3174     FixedArrayBase*, int);
3175 template void Heap::RightTrimFixedArray<Heap::CONCURRENT_TO_SWEEPER>(
3176     FixedArrayBase*, int);
3177 
3178 
3179 template<Heap::InvocationMode mode>
RightTrimFixedArray(FixedArrayBase * object,int elements_to_trim)3180 void Heap::RightTrimFixedArray(FixedArrayBase* object, int elements_to_trim) {
3181   const int len = object->length();
3182   DCHECK_LE(elements_to_trim, len);
3183   DCHECK_GE(elements_to_trim, 0);
3184 
3185   int bytes_to_trim;
3186   if (object->IsFixedTypedArrayBase()) {
3187     InstanceType type = object->map()->instance_type();
3188     bytes_to_trim =
3189         FixedTypedArrayBase::TypedArraySize(type, len) -
3190         FixedTypedArrayBase::TypedArraySize(type, len - elements_to_trim);
3191   } else if (object->IsByteArray()) {
3192     int new_size = ByteArray::SizeFor(len - elements_to_trim);
3193     bytes_to_trim = ByteArray::SizeFor(len) - new_size;
3194     DCHECK_GE(bytes_to_trim, 0);
3195   } else {
3196     const int element_size =
3197         object->IsFixedArray() ? kPointerSize : kDoubleSize;
3198     bytes_to_trim = elements_to_trim * element_size;
3199   }
3200 
3201 
3202   // For now this trick is only applied to objects in new and paged space.
3203   DCHECK(object->map() != fixed_cow_array_map());
3204 
3205   if (bytes_to_trim == 0) {
3206     // No need to create filler and update live bytes counters, just initialize
3207     // header of the trimmed array.
3208     object->synchronized_set_length(len - elements_to_trim);
3209     return;
3210   }
3211 
3212   // Calculate location of new array end.
3213   Address new_end = object->address() + object->Size() - bytes_to_trim;
3214 
3215   // Technically in new space this write might be omitted (except for
3216   // debug mode which iterates through the heap), but to play safer
3217   // we still do it.
3218   // We do not create a filler for objects in large object space.
3219   // TODO(hpayer): We should shrink the large object page if the size
3220   // of the object changed significantly.
3221   if (!lo_space()->Contains(object)) {
3222     CreateFillerObjectAt(new_end, bytes_to_trim);
3223   }
3224 
3225   // Initialize header of the trimmed array. We are storing the new length
3226   // using release store after creating a filler for the left-over space to
3227   // avoid races with the sweeper thread.
3228   object->synchronized_set_length(len - elements_to_trim);
3229 
3230   // Maintain consistency of live bytes during incremental marking
3231   AdjustLiveBytes(object, -bytes_to_trim, mode);
3232 
3233   // Notify the heap profiler of change in object layout. The array may not be
3234   // moved during GC, and size has to be adjusted nevertheless.
3235   HeapProfiler* profiler = isolate()->heap_profiler();
3236   if (profiler->is_tracking_allocations()) {
3237     profiler->UpdateObjectSizeEvent(object->address(), object->Size());
3238   }
3239 }
3240 
3241 
AllocateFixedTypedArrayWithExternalPointer(int length,ExternalArrayType array_type,void * external_pointer,PretenureFlag pretenure)3242 AllocationResult Heap::AllocateFixedTypedArrayWithExternalPointer(
3243     int length, ExternalArrayType array_type, void* external_pointer,
3244     PretenureFlag pretenure) {
3245   int size = FixedTypedArrayBase::kHeaderSize;
3246   AllocationSpace space = SelectSpace(pretenure);
3247   HeapObject* result = nullptr;
3248   {
3249     AllocationResult allocation = AllocateRaw(size, space);
3250     if (!allocation.To(&result)) return allocation;
3251   }
3252 
3253   result->set_map_no_write_barrier(MapForFixedTypedArray(array_type));
3254   FixedTypedArrayBase* elements = FixedTypedArrayBase::cast(result);
3255   elements->set_base_pointer(Smi::FromInt(0), SKIP_WRITE_BARRIER);
3256   elements->set_external_pointer(external_pointer, SKIP_WRITE_BARRIER);
3257   elements->set_length(length);
3258   return elements;
3259 }
3260 
ForFixedTypedArray(ExternalArrayType array_type,int * element_size,ElementsKind * element_kind)3261 static void ForFixedTypedArray(ExternalArrayType array_type, int* element_size,
3262                                ElementsKind* element_kind) {
3263   switch (array_type) {
3264 #define TYPED_ARRAY_CASE(Type, type, TYPE, ctype, size) \
3265   case kExternal##Type##Array:                          \
3266     *element_size = size;                               \
3267     *element_kind = TYPE##_ELEMENTS;                    \
3268     return;
3269 
3270     TYPED_ARRAYS(TYPED_ARRAY_CASE)
3271 #undef TYPED_ARRAY_CASE
3272 
3273     default:
3274       *element_size = 0;               // Bogus
3275       *element_kind = UINT8_ELEMENTS;  // Bogus
3276       UNREACHABLE();
3277   }
3278 }
3279 
3280 
AllocateFixedTypedArray(int length,ExternalArrayType array_type,bool initialize,PretenureFlag pretenure)3281 AllocationResult Heap::AllocateFixedTypedArray(int length,
3282                                                ExternalArrayType array_type,
3283                                                bool initialize,
3284                                                PretenureFlag pretenure) {
3285   int element_size;
3286   ElementsKind elements_kind;
3287   ForFixedTypedArray(array_type, &element_size, &elements_kind);
3288   int size = OBJECT_POINTER_ALIGN(length * element_size +
3289                                   FixedTypedArrayBase::kDataOffset);
3290   AllocationSpace space = SelectSpace(pretenure);
3291 
3292   HeapObject* object = nullptr;
3293   AllocationResult allocation = AllocateRaw(
3294       size, space,
3295       array_type == kExternalFloat64Array ? kDoubleAligned : kWordAligned);
3296   if (!allocation.To(&object)) return allocation;
3297 
3298   object->set_map_no_write_barrier(MapForFixedTypedArray(array_type));
3299   FixedTypedArrayBase* elements = FixedTypedArrayBase::cast(object);
3300   elements->set_base_pointer(elements, SKIP_WRITE_BARRIER);
3301   elements->set_external_pointer(
3302       ExternalReference::fixed_typed_array_base_data_offset().address(),
3303       SKIP_WRITE_BARRIER);
3304   elements->set_length(length);
3305   if (initialize) memset(elements->DataPtr(), 0, elements->DataSize());
3306   return elements;
3307 }
3308 
3309 
AllocateCode(int object_size,bool immovable)3310 AllocationResult Heap::AllocateCode(int object_size, bool immovable) {
3311   DCHECK(IsAligned(static_cast<intptr_t>(object_size), kCodeAlignment));
3312   AllocationResult allocation = AllocateRaw(object_size, CODE_SPACE);
3313 
3314   HeapObject* result = nullptr;
3315   if (!allocation.To(&result)) return allocation;
3316 
3317   if (immovable) {
3318     Address address = result->address();
3319     // Code objects which should stay at a fixed address are allocated either
3320     // in the first page of code space (objects on the first page of each space
3321     // are never moved) or in large object space.
3322     if (!code_space_->FirstPage()->Contains(address) &&
3323         MemoryChunk::FromAddress(address)->owner()->identity() != LO_SPACE) {
3324       // Discard the first code allocation, which was on a page where it could
3325       // be moved.
3326       CreateFillerObjectAt(result->address(), object_size);
3327       allocation = lo_space_->AllocateRaw(object_size, EXECUTABLE);
3328       if (!allocation.To(&result)) return allocation;
3329       OnAllocationEvent(result, object_size);
3330     }
3331   }
3332 
3333   result->set_map_no_write_barrier(code_map());
3334   Code* code = Code::cast(result);
3335   DCHECK(IsAligned(bit_cast<intptr_t>(code->address()), kCodeAlignment));
3336   DCHECK(isolate_->code_range() == NULL || !isolate_->code_range()->valid() ||
3337          isolate_->code_range()->contains(code->address()) ||
3338          object_size <= code_space()->AreaSize());
3339   code->set_gc_metadata(Smi::FromInt(0));
3340   code->set_ic_age(global_ic_age_);
3341   return code;
3342 }
3343 
3344 
CopyCode(Code * code)3345 AllocationResult Heap::CopyCode(Code* code) {
3346   AllocationResult allocation;
3347 
3348   HeapObject* result = nullptr;
3349   // Allocate an object the same size as the code object.
3350   int obj_size = code->Size();
3351   allocation = AllocateRaw(obj_size, CODE_SPACE);
3352   if (!allocation.To(&result)) return allocation;
3353 
3354   // Copy code object.
3355   Address old_addr = code->address();
3356   Address new_addr = result->address();
3357   CopyBlock(new_addr, old_addr, obj_size);
3358   Code* new_code = Code::cast(result);
3359 
3360   // Relocate the copy.
3361   DCHECK(IsAligned(bit_cast<intptr_t>(new_code->address()), kCodeAlignment));
3362   DCHECK(isolate_->code_range() == NULL || !isolate_->code_range()->valid() ||
3363          isolate_->code_range()->contains(code->address()) ||
3364          obj_size <= code_space()->AreaSize());
3365   new_code->Relocate(new_addr - old_addr);
3366   return new_code;
3367 }
3368 
3369 
CopyCode(Code * code,Vector<byte> reloc_info)3370 AllocationResult Heap::CopyCode(Code* code, Vector<byte> reloc_info) {
3371   // Allocate ByteArray before the Code object, so that we do not risk
3372   // leaving uninitialized Code object (and breaking the heap).
3373   ByteArray* reloc_info_array = nullptr;
3374   {
3375     AllocationResult allocation =
3376         AllocateByteArray(reloc_info.length(), TENURED);
3377     if (!allocation.To(&reloc_info_array)) return allocation;
3378   }
3379 
3380   int new_body_size = RoundUp(code->instruction_size(), kObjectAlignment);
3381 
3382   int new_obj_size = Code::SizeFor(new_body_size);
3383 
3384   Address old_addr = code->address();
3385 
3386   size_t relocation_offset =
3387       static_cast<size_t>(code->instruction_end() - old_addr);
3388 
3389   HeapObject* result = nullptr;
3390   AllocationResult allocation = AllocateRaw(new_obj_size, CODE_SPACE);
3391   if (!allocation.To(&result)) return allocation;
3392 
3393   // Copy code object.
3394   Address new_addr = result->address();
3395 
3396   // Copy header and instructions.
3397   CopyBytes(new_addr, old_addr, relocation_offset);
3398 
3399   Code* new_code = Code::cast(result);
3400   new_code->set_relocation_info(reloc_info_array);
3401 
3402   // Copy patched rinfo.
3403   CopyBytes(new_code->relocation_start(), reloc_info.start(),
3404             static_cast<size_t>(reloc_info.length()));
3405 
3406   // Relocate the copy.
3407   DCHECK(IsAligned(bit_cast<intptr_t>(new_code->address()), kCodeAlignment));
3408   DCHECK(isolate_->code_range() == NULL || !isolate_->code_range()->valid() ||
3409          isolate_->code_range()->contains(code->address()) ||
3410          new_obj_size <= code_space()->AreaSize());
3411 
3412   new_code->Relocate(new_addr - old_addr);
3413 
3414 #ifdef VERIFY_HEAP
3415   if (FLAG_verify_heap) code->ObjectVerify();
3416 #endif
3417   return new_code;
3418 }
3419 
3420 
InitializeAllocationMemento(AllocationMemento * memento,AllocationSite * allocation_site)3421 void Heap::InitializeAllocationMemento(AllocationMemento* memento,
3422                                        AllocationSite* allocation_site) {
3423   memento->set_map_no_write_barrier(allocation_memento_map());
3424   DCHECK(allocation_site->map() == allocation_site_map());
3425   memento->set_allocation_site(allocation_site, SKIP_WRITE_BARRIER);
3426   if (FLAG_allocation_site_pretenuring) {
3427     allocation_site->IncrementMementoCreateCount();
3428   }
3429 }
3430 
3431 
Allocate(Map * map,AllocationSpace space,AllocationSite * allocation_site)3432 AllocationResult Heap::Allocate(Map* map, AllocationSpace space,
3433                                 AllocationSite* allocation_site) {
3434   DCHECK(gc_state_ == NOT_IN_GC);
3435   DCHECK(map->instance_type() != MAP_TYPE);
3436   int size = map->instance_size();
3437   if (allocation_site != NULL) {
3438     size += AllocationMemento::kSize;
3439   }
3440   HeapObject* result = nullptr;
3441   AllocationResult allocation = AllocateRaw(size, space);
3442   if (!allocation.To(&result)) return allocation;
3443   // No need for write barrier since object is white and map is in old space.
3444   result->set_map_no_write_barrier(map);
3445   if (allocation_site != NULL) {
3446     AllocationMemento* alloc_memento = reinterpret_cast<AllocationMemento*>(
3447         reinterpret_cast<Address>(result) + map->instance_size());
3448     InitializeAllocationMemento(alloc_memento, allocation_site);
3449   }
3450   return result;
3451 }
3452 
3453 
InitializeJSObjectFromMap(JSObject * obj,FixedArray * properties,Map * map)3454 void Heap::InitializeJSObjectFromMap(JSObject* obj, FixedArray* properties,
3455                                      Map* map) {
3456   obj->set_properties(properties);
3457   obj->initialize_elements();
3458   // TODO(1240798): Initialize the object's body using valid initial values
3459   // according to the object's initial map.  For example, if the map's
3460   // instance type is JS_ARRAY_TYPE, the length field should be initialized
3461   // to a number (e.g. Smi::FromInt(0)) and the elements initialized to a
3462   // fixed array (e.g. Heap::empty_fixed_array()).  Currently, the object
3463   // verification code has to cope with (temporarily) invalid objects.  See
3464   // for example, JSArray::JSArrayVerify).
3465   InitializeJSObjectBody(obj, map, JSObject::kHeaderSize);
3466 }
3467 
3468 
InitializeJSObjectBody(JSObject * obj,Map * map,int start_offset)3469 void Heap::InitializeJSObjectBody(JSObject* obj, Map* map, int start_offset) {
3470   if (start_offset == map->instance_size()) return;
3471   DCHECK_LT(start_offset, map->instance_size());
3472 
3473   Object* filler;
3474   // We cannot always fill with one_pointer_filler_map because objects
3475   // created from API functions expect their internal fields to be initialized
3476   // with undefined_value.
3477   // Pre-allocated fields need to be initialized with undefined_value as well
3478   // so that object accesses before the constructor completes (e.g. in the
3479   // debugger) will not cause a crash.
3480 
3481   // In case of Array subclassing the |map| could already be transitioned
3482   // to different elements kind from the initial map on which we track slack.
3483   Map* initial_map = map->FindRootMap();
3484   if (initial_map->IsInobjectSlackTrackingInProgress()) {
3485     // We might want to shrink the object later.
3486     filler = Heap::one_pointer_filler_map();
3487   } else {
3488     filler = Heap::undefined_value();
3489   }
3490   obj->InitializeBody(map, start_offset, Heap::undefined_value(), filler);
3491   initial_map->InobjectSlackTrackingStep();
3492 }
3493 
3494 
AllocateJSObjectFromMap(Map * map,PretenureFlag pretenure,AllocationSite * allocation_site)3495 AllocationResult Heap::AllocateJSObjectFromMap(
3496     Map* map, PretenureFlag pretenure, AllocationSite* allocation_site) {
3497   // JSFunctions should be allocated using AllocateFunction to be
3498   // properly initialized.
3499   DCHECK(map->instance_type() != JS_FUNCTION_TYPE);
3500 
3501   // Both types of global objects should be allocated using
3502   // AllocateGlobalObject to be properly initialized.
3503   DCHECK(map->instance_type() != JS_GLOBAL_OBJECT_TYPE);
3504 
3505   // Allocate the backing storage for the properties.
3506   FixedArray* properties = empty_fixed_array();
3507 
3508   // Allocate the JSObject.
3509   AllocationSpace space = SelectSpace(pretenure);
3510   JSObject* js_obj = nullptr;
3511   AllocationResult allocation = Allocate(map, space, allocation_site);
3512   if (!allocation.To(&js_obj)) return allocation;
3513 
3514   // Initialize the JSObject.
3515   InitializeJSObjectFromMap(js_obj, properties, map);
3516   DCHECK(js_obj->HasFastElements() || js_obj->HasFixedTypedArrayElements());
3517   return js_obj;
3518 }
3519 
3520 
AllocateJSObject(JSFunction * constructor,PretenureFlag pretenure,AllocationSite * allocation_site)3521 AllocationResult Heap::AllocateJSObject(JSFunction* constructor,
3522                                         PretenureFlag pretenure,
3523                                         AllocationSite* allocation_site) {
3524   DCHECK(constructor->has_initial_map());
3525 
3526   // Allocate the object based on the constructors initial map.
3527   AllocationResult allocation = AllocateJSObjectFromMap(
3528       constructor->initial_map(), pretenure, allocation_site);
3529 #ifdef DEBUG
3530   // Make sure result is NOT a global object if valid.
3531   HeapObject* obj = nullptr;
3532   DCHECK(!allocation.To(&obj) || !obj->IsJSGlobalObject());
3533 #endif
3534   return allocation;
3535 }
3536 
3537 
CopyJSObject(JSObject * source,AllocationSite * site)3538 AllocationResult Heap::CopyJSObject(JSObject* source, AllocationSite* site) {
3539   // Make the clone.
3540   Map* map = source->map();
3541 
3542   // We can only clone regexps, normal objects or arrays. Copying anything else
3543   // will break invariants.
3544   CHECK(map->instance_type() == JS_REGEXP_TYPE ||
3545         map->instance_type() == JS_OBJECT_TYPE ||
3546         map->instance_type() == JS_ARRAY_TYPE);
3547 
3548   int object_size = map->instance_size();
3549   HeapObject* clone = nullptr;
3550 
3551   DCHECK(site == NULL || AllocationSite::CanTrack(map->instance_type()));
3552 
3553   int adjusted_object_size =
3554       site != NULL ? object_size + AllocationMemento::kSize : object_size;
3555   AllocationResult allocation = AllocateRaw(adjusted_object_size, NEW_SPACE);
3556   if (!allocation.To(&clone)) return allocation;
3557 
3558   SLOW_DCHECK(InNewSpace(clone));
3559   // Since we know the clone is allocated in new space, we can copy
3560   // the contents without worrying about updating the write barrier.
3561   CopyBlock(clone->address(), source->address(), object_size);
3562 
3563   if (site != NULL) {
3564     AllocationMemento* alloc_memento = reinterpret_cast<AllocationMemento*>(
3565         reinterpret_cast<Address>(clone) + object_size);
3566     InitializeAllocationMemento(alloc_memento, site);
3567   }
3568 
3569   SLOW_DCHECK(JSObject::cast(clone)->GetElementsKind() ==
3570               source->GetElementsKind());
3571   FixedArrayBase* elements = FixedArrayBase::cast(source->elements());
3572   FixedArray* properties = FixedArray::cast(source->properties());
3573   // Update elements if necessary.
3574   if (elements->length() > 0) {
3575     FixedArrayBase* elem = nullptr;
3576     {
3577       AllocationResult allocation;
3578       if (elements->map() == fixed_cow_array_map()) {
3579         allocation = FixedArray::cast(elements);
3580       } else if (source->HasFastDoubleElements()) {
3581         allocation = CopyFixedDoubleArray(FixedDoubleArray::cast(elements));
3582       } else {
3583         allocation = CopyFixedArray(FixedArray::cast(elements));
3584       }
3585       if (!allocation.To(&elem)) return allocation;
3586     }
3587     JSObject::cast(clone)->set_elements(elem, SKIP_WRITE_BARRIER);
3588   }
3589   // Update properties if necessary.
3590   if (properties->length() > 0) {
3591     FixedArray* prop = nullptr;
3592     {
3593       AllocationResult allocation = CopyFixedArray(properties);
3594       if (!allocation.To(&prop)) return allocation;
3595     }
3596     JSObject::cast(clone)->set_properties(prop, SKIP_WRITE_BARRIER);
3597   }
3598   // Return the new clone.
3599   return clone;
3600 }
3601 
3602 
WriteOneByteData(Vector<const char> vector,uint8_t * chars,int len)3603 static inline void WriteOneByteData(Vector<const char> vector, uint8_t* chars,
3604                                     int len) {
3605   // Only works for one byte strings.
3606   DCHECK(vector.length() == len);
3607   MemCopy(chars, vector.start(), len);
3608 }
3609 
WriteTwoByteData(Vector<const char> vector,uint16_t * chars,int len)3610 static inline void WriteTwoByteData(Vector<const char> vector, uint16_t* chars,
3611                                     int len) {
3612   const uint8_t* stream = reinterpret_cast<const uint8_t*>(vector.start());
3613   size_t stream_length = vector.length();
3614   while (stream_length != 0) {
3615     size_t consumed = 0;
3616     uint32_t c = unibrow::Utf8::ValueOf(stream, stream_length, &consumed);
3617     DCHECK(c != unibrow::Utf8::kBadChar);
3618     DCHECK(consumed <= stream_length);
3619     stream_length -= consumed;
3620     stream += consumed;
3621     if (c > unibrow::Utf16::kMaxNonSurrogateCharCode) {
3622       len -= 2;
3623       if (len < 0) break;
3624       *chars++ = unibrow::Utf16::LeadSurrogate(c);
3625       *chars++ = unibrow::Utf16::TrailSurrogate(c);
3626     } else {
3627       len -= 1;
3628       if (len < 0) break;
3629       *chars++ = c;
3630     }
3631   }
3632   DCHECK(stream_length == 0);
3633   DCHECK(len == 0);
3634 }
3635 
3636 
WriteOneByteData(String * s,uint8_t * chars,int len)3637 static inline void WriteOneByteData(String* s, uint8_t* chars, int len) {
3638   DCHECK(s->length() == len);
3639   String::WriteToFlat(s, chars, 0, len);
3640 }
3641 
3642 
WriteTwoByteData(String * s,uint16_t * chars,int len)3643 static inline void WriteTwoByteData(String* s, uint16_t* chars, int len) {
3644   DCHECK(s->length() == len);
3645   String::WriteToFlat(s, chars, 0, len);
3646 }
3647 
3648 
3649 template <bool is_one_byte, typename T>
AllocateInternalizedStringImpl(T t,int chars,uint32_t hash_field)3650 AllocationResult Heap::AllocateInternalizedStringImpl(T t, int chars,
3651                                                       uint32_t hash_field) {
3652   DCHECK(chars >= 0);
3653   // Compute map and object size.
3654   int size;
3655   Map* map;
3656 
3657   DCHECK_LE(0, chars);
3658   DCHECK_GE(String::kMaxLength, chars);
3659   if (is_one_byte) {
3660     map = one_byte_internalized_string_map();
3661     size = SeqOneByteString::SizeFor(chars);
3662   } else {
3663     map = internalized_string_map();
3664     size = SeqTwoByteString::SizeFor(chars);
3665   }
3666 
3667   // Allocate string.
3668   HeapObject* result = nullptr;
3669   {
3670     AllocationResult allocation = AllocateRaw(size, OLD_SPACE);
3671     if (!allocation.To(&result)) return allocation;
3672   }
3673 
3674   result->set_map_no_write_barrier(map);
3675   // Set length and hash fields of the allocated string.
3676   String* answer = String::cast(result);
3677   answer->set_length(chars);
3678   answer->set_hash_field(hash_field);
3679 
3680   DCHECK_EQ(size, answer->Size());
3681 
3682   if (is_one_byte) {
3683     WriteOneByteData(t, SeqOneByteString::cast(answer)->GetChars(), chars);
3684   } else {
3685     WriteTwoByteData(t, SeqTwoByteString::cast(answer)->GetChars(), chars);
3686   }
3687   return answer;
3688 }
3689 
3690 
3691 // Need explicit instantiations.
3692 template AllocationResult Heap::AllocateInternalizedStringImpl<true>(String*,
3693                                                                      int,
3694                                                                      uint32_t);
3695 template AllocationResult Heap::AllocateInternalizedStringImpl<false>(String*,
3696                                                                       int,
3697                                                                       uint32_t);
3698 template AllocationResult Heap::AllocateInternalizedStringImpl<false>(
3699     Vector<const char>, int, uint32_t);
3700 
3701 
AllocateRawOneByteString(int length,PretenureFlag pretenure)3702 AllocationResult Heap::AllocateRawOneByteString(int length,
3703                                                 PretenureFlag pretenure) {
3704   DCHECK_LE(0, length);
3705   DCHECK_GE(String::kMaxLength, length);
3706   int size = SeqOneByteString::SizeFor(length);
3707   DCHECK(size <= SeqOneByteString::kMaxSize);
3708   AllocationSpace space = SelectSpace(pretenure);
3709 
3710   HeapObject* result = nullptr;
3711   {
3712     AllocationResult allocation = AllocateRaw(size, space);
3713     if (!allocation.To(&result)) return allocation;
3714   }
3715 
3716   // Partially initialize the object.
3717   result->set_map_no_write_barrier(one_byte_string_map());
3718   String::cast(result)->set_length(length);
3719   String::cast(result)->set_hash_field(String::kEmptyHashField);
3720   DCHECK_EQ(size, HeapObject::cast(result)->Size());
3721 
3722   return result;
3723 }
3724 
3725 
AllocateRawTwoByteString(int length,PretenureFlag pretenure)3726 AllocationResult Heap::AllocateRawTwoByteString(int length,
3727                                                 PretenureFlag pretenure) {
3728   DCHECK_LE(0, length);
3729   DCHECK_GE(String::kMaxLength, length);
3730   int size = SeqTwoByteString::SizeFor(length);
3731   DCHECK(size <= SeqTwoByteString::kMaxSize);
3732   AllocationSpace space = SelectSpace(pretenure);
3733 
3734   HeapObject* result = nullptr;
3735   {
3736     AllocationResult allocation = AllocateRaw(size, space);
3737     if (!allocation.To(&result)) return allocation;
3738   }
3739 
3740   // Partially initialize the object.
3741   result->set_map_no_write_barrier(string_map());
3742   String::cast(result)->set_length(length);
3743   String::cast(result)->set_hash_field(String::kEmptyHashField);
3744   DCHECK_EQ(size, HeapObject::cast(result)->Size());
3745   return result;
3746 }
3747 
3748 
AllocateEmptyFixedArray()3749 AllocationResult Heap::AllocateEmptyFixedArray() {
3750   int size = FixedArray::SizeFor(0);
3751   HeapObject* result = nullptr;
3752   {
3753     AllocationResult allocation = AllocateRaw(size, OLD_SPACE);
3754     if (!allocation.To(&result)) return allocation;
3755   }
3756   // Initialize the object.
3757   result->set_map_no_write_barrier(fixed_array_map());
3758   FixedArray::cast(result)->set_length(0);
3759   return result;
3760 }
3761 
3762 
CopyAndTenureFixedCOWArray(FixedArray * src)3763 AllocationResult Heap::CopyAndTenureFixedCOWArray(FixedArray* src) {
3764   if (!InNewSpace(src)) {
3765     return src;
3766   }
3767 
3768   int len = src->length();
3769   HeapObject* obj = nullptr;
3770   {
3771     AllocationResult allocation = AllocateRawFixedArray(len, TENURED);
3772     if (!allocation.To(&obj)) return allocation;
3773   }
3774   obj->set_map_no_write_barrier(fixed_array_map());
3775   FixedArray* result = FixedArray::cast(obj);
3776   result->set_length(len);
3777 
3778   // Copy the content.
3779   DisallowHeapAllocation no_gc;
3780   WriteBarrierMode mode = result->GetWriteBarrierMode(no_gc);
3781   for (int i = 0; i < len; i++) result->set(i, src->get(i), mode);
3782 
3783   // TODO(mvstanton): The map is set twice because of protection against calling
3784   // set() on a COW FixedArray. Issue v8:3221 created to track this, and
3785   // we might then be able to remove this whole method.
3786   HeapObject::cast(obj)->set_map_no_write_barrier(fixed_cow_array_map());
3787   return result;
3788 }
3789 
3790 
AllocateEmptyFixedTypedArray(ExternalArrayType array_type)3791 AllocationResult Heap::AllocateEmptyFixedTypedArray(
3792     ExternalArrayType array_type) {
3793   return AllocateFixedTypedArray(0, array_type, false, TENURED);
3794 }
3795 
3796 
CopyFixedArrayAndGrow(FixedArray * src,int grow_by,PretenureFlag pretenure)3797 AllocationResult Heap::CopyFixedArrayAndGrow(FixedArray* src, int grow_by,
3798                                              PretenureFlag pretenure) {
3799   int old_len = src->length();
3800   int new_len = old_len + grow_by;
3801   DCHECK(new_len >= old_len);
3802   HeapObject* obj = nullptr;
3803   {
3804     AllocationResult allocation = AllocateRawFixedArray(new_len, pretenure);
3805     if (!allocation.To(&obj)) return allocation;
3806   }
3807   obj->set_map_no_write_barrier(fixed_array_map());
3808   FixedArray* result = FixedArray::cast(obj);
3809   result->set_length(new_len);
3810 
3811   // Copy the content.
3812   DisallowHeapAllocation no_gc;
3813   WriteBarrierMode mode = result->GetWriteBarrierMode(no_gc);
3814   for (int i = 0; i < old_len; i++) result->set(i, src->get(i), mode);
3815   MemsetPointer(result->data_start() + old_len, undefined_value(), grow_by);
3816   return result;
3817 }
3818 
3819 
CopyFixedArrayWithMap(FixedArray * src,Map * map)3820 AllocationResult Heap::CopyFixedArrayWithMap(FixedArray* src, Map* map) {
3821   int len = src->length();
3822   HeapObject* obj = nullptr;
3823   {
3824     AllocationResult allocation = AllocateRawFixedArray(len, NOT_TENURED);
3825     if (!allocation.To(&obj)) return allocation;
3826   }
3827   if (InNewSpace(obj)) {
3828     obj->set_map_no_write_barrier(map);
3829     CopyBlock(obj->address() + kPointerSize, src->address() + kPointerSize,
3830               FixedArray::SizeFor(len) - kPointerSize);
3831     return obj;
3832   }
3833   obj->set_map_no_write_barrier(map);
3834   FixedArray* result = FixedArray::cast(obj);
3835   result->set_length(len);
3836 
3837   // Copy the content.
3838   DisallowHeapAllocation no_gc;
3839   WriteBarrierMode mode = result->GetWriteBarrierMode(no_gc);
3840   for (int i = 0; i < len; i++) result->set(i, src->get(i), mode);
3841   return result;
3842 }
3843 
3844 
CopyFixedDoubleArrayWithMap(FixedDoubleArray * src,Map * map)3845 AllocationResult Heap::CopyFixedDoubleArrayWithMap(FixedDoubleArray* src,
3846                                                    Map* map) {
3847   int len = src->length();
3848   HeapObject* obj = nullptr;
3849   {
3850     AllocationResult allocation = AllocateRawFixedDoubleArray(len, NOT_TENURED);
3851     if (!allocation.To(&obj)) return allocation;
3852   }
3853   obj->set_map_no_write_barrier(map);
3854   CopyBlock(obj->address() + FixedDoubleArray::kLengthOffset,
3855             src->address() + FixedDoubleArray::kLengthOffset,
3856             FixedDoubleArray::SizeFor(len) - FixedDoubleArray::kLengthOffset);
3857   return obj;
3858 }
3859 
3860 
AllocateRawFixedArray(int length,PretenureFlag pretenure)3861 AllocationResult Heap::AllocateRawFixedArray(int length,
3862                                              PretenureFlag pretenure) {
3863   if (length < 0 || length > FixedArray::kMaxLength) {
3864     v8::internal::Heap::FatalProcessOutOfMemory("invalid array length", true);
3865   }
3866   int size = FixedArray::SizeFor(length);
3867   AllocationSpace space = SelectSpace(pretenure);
3868 
3869   return AllocateRaw(size, space);
3870 }
3871 
3872 
AllocateFixedArrayWithFiller(int length,PretenureFlag pretenure,Object * filler)3873 AllocationResult Heap::AllocateFixedArrayWithFiller(int length,
3874                                                     PretenureFlag pretenure,
3875                                                     Object* filler) {
3876   DCHECK(length >= 0);
3877   DCHECK(empty_fixed_array()->IsFixedArray());
3878   if (length == 0) return empty_fixed_array();
3879 
3880   DCHECK(!InNewSpace(filler));
3881   HeapObject* result = nullptr;
3882   {
3883     AllocationResult allocation = AllocateRawFixedArray(length, pretenure);
3884     if (!allocation.To(&result)) return allocation;
3885   }
3886 
3887   result->set_map_no_write_barrier(fixed_array_map());
3888   FixedArray* array = FixedArray::cast(result);
3889   array->set_length(length);
3890   MemsetPointer(array->data_start(), filler, length);
3891   return array;
3892 }
3893 
3894 
AllocateFixedArray(int length,PretenureFlag pretenure)3895 AllocationResult Heap::AllocateFixedArray(int length, PretenureFlag pretenure) {
3896   return AllocateFixedArrayWithFiller(length, pretenure, undefined_value());
3897 }
3898 
3899 
AllocateUninitializedFixedArray(int length)3900 AllocationResult Heap::AllocateUninitializedFixedArray(int length) {
3901   if (length == 0) return empty_fixed_array();
3902 
3903   HeapObject* obj = nullptr;
3904   {
3905     AllocationResult allocation = AllocateRawFixedArray(length, NOT_TENURED);
3906     if (!allocation.To(&obj)) return allocation;
3907   }
3908 
3909   obj->set_map_no_write_barrier(fixed_array_map());
3910   FixedArray::cast(obj)->set_length(length);
3911   return obj;
3912 }
3913 
3914 
AllocateUninitializedFixedDoubleArray(int length,PretenureFlag pretenure)3915 AllocationResult Heap::AllocateUninitializedFixedDoubleArray(
3916     int length, PretenureFlag pretenure) {
3917   if (length == 0) return empty_fixed_array();
3918 
3919   HeapObject* elements = nullptr;
3920   AllocationResult allocation = AllocateRawFixedDoubleArray(length, pretenure);
3921   if (!allocation.To(&elements)) return allocation;
3922 
3923   elements->set_map_no_write_barrier(fixed_double_array_map());
3924   FixedDoubleArray::cast(elements)->set_length(length);
3925   return elements;
3926 }
3927 
3928 
AllocateRawFixedDoubleArray(int length,PretenureFlag pretenure)3929 AllocationResult Heap::AllocateRawFixedDoubleArray(int length,
3930                                                    PretenureFlag pretenure) {
3931   if (length < 0 || length > FixedDoubleArray::kMaxLength) {
3932     v8::internal::Heap::FatalProcessOutOfMemory("invalid array length",
3933                                                 kDoubleAligned);
3934   }
3935   int size = FixedDoubleArray::SizeFor(length);
3936   AllocationSpace space = SelectSpace(pretenure);
3937 
3938   HeapObject* object = nullptr;
3939   {
3940     AllocationResult allocation = AllocateRaw(size, space, kDoubleAligned);
3941     if (!allocation.To(&object)) return allocation;
3942   }
3943 
3944   return object;
3945 }
3946 
3947 
AllocateSymbol()3948 AllocationResult Heap::AllocateSymbol() {
3949   // Statically ensure that it is safe to allocate symbols in paged spaces.
3950   STATIC_ASSERT(Symbol::kSize <= Page::kMaxRegularHeapObjectSize);
3951 
3952   HeapObject* result = nullptr;
3953   AllocationResult allocation = AllocateRaw(Symbol::kSize, OLD_SPACE);
3954   if (!allocation.To(&result)) return allocation;
3955 
3956   result->set_map_no_write_barrier(symbol_map());
3957 
3958   // Generate a random hash value.
3959   int hash;
3960   int attempts = 0;
3961   do {
3962     hash = isolate()->random_number_generator()->NextInt() & Name::kHashBitMask;
3963     attempts++;
3964   } while (hash == 0 && attempts < 30);
3965   if (hash == 0) hash = 1;  // never return 0
3966 
3967   Symbol::cast(result)
3968       ->set_hash_field(Name::kIsNotArrayIndexMask | (hash << Name::kHashShift));
3969   Symbol::cast(result)->set_name(undefined_value());
3970   Symbol::cast(result)->set_flags(0);
3971 
3972   DCHECK(!Symbol::cast(result)->is_private());
3973   return result;
3974 }
3975 
3976 
AllocateStruct(InstanceType type)3977 AllocationResult Heap::AllocateStruct(InstanceType type) {
3978   Map* map;
3979   switch (type) {
3980 #define MAKE_CASE(NAME, Name, name) \
3981   case NAME##_TYPE:                 \
3982     map = name##_map();             \
3983     break;
3984     STRUCT_LIST(MAKE_CASE)
3985 #undef MAKE_CASE
3986     default:
3987       UNREACHABLE();
3988       return exception();
3989   }
3990   int size = map->instance_size();
3991   Struct* result = nullptr;
3992   {
3993     AllocationResult allocation = Allocate(map, OLD_SPACE);
3994     if (!allocation.To(&result)) return allocation;
3995   }
3996   result->InitializeBody(size);
3997   return result;
3998 }
3999 
4000 
IsHeapIterable()4001 bool Heap::IsHeapIterable() {
4002   // TODO(hpayer): This function is not correct. Allocation folding in old
4003   // space breaks the iterability.
4004   return new_space_top_after_last_gc_ == new_space()->top();
4005 }
4006 
4007 
MakeHeapIterable()4008 void Heap::MakeHeapIterable() {
4009   DCHECK(AllowHeapAllocation::IsAllowed());
4010   if (!IsHeapIterable()) {
4011     CollectAllGarbage(kMakeHeapIterableMask, "Heap::MakeHeapIterable");
4012   }
4013   if (mark_compact_collector()->sweeping_in_progress()) {
4014     mark_compact_collector()->EnsureSweepingCompleted();
4015   }
4016   DCHECK(IsHeapIterable());
4017 }
4018 
4019 
ComputeMutatorUtilization(double mutator_speed,double gc_speed)4020 static double ComputeMutatorUtilization(double mutator_speed, double gc_speed) {
4021   const double kMinMutatorUtilization = 0.0;
4022   const double kConservativeGcSpeedInBytesPerMillisecond = 200000;
4023   if (mutator_speed == 0) return kMinMutatorUtilization;
4024   if (gc_speed == 0) gc_speed = kConservativeGcSpeedInBytesPerMillisecond;
4025   // Derivation:
4026   // mutator_utilization = mutator_time / (mutator_time + gc_time)
4027   // mutator_time = 1 / mutator_speed
4028   // gc_time = 1 / gc_speed
4029   // mutator_utilization = (1 / mutator_speed) /
4030   //                       (1 / mutator_speed + 1 / gc_speed)
4031   // mutator_utilization = gc_speed / (mutator_speed + gc_speed)
4032   return gc_speed / (mutator_speed + gc_speed);
4033 }
4034 
4035 
YoungGenerationMutatorUtilization()4036 double Heap::YoungGenerationMutatorUtilization() {
4037   double mutator_speed = static_cast<double>(
4038       tracer()->NewSpaceAllocationThroughputInBytesPerMillisecond());
4039   double gc_speed = static_cast<double>(
4040       tracer()->ScavengeSpeedInBytesPerMillisecond(kForSurvivedObjects));
4041   double result = ComputeMutatorUtilization(mutator_speed, gc_speed);
4042   if (FLAG_trace_mutator_utilization) {
4043     PrintIsolate(isolate(),
4044                  "Young generation mutator utilization = %.3f ("
4045                  "mutator_speed=%.f, gc_speed=%.f)\n",
4046                  result, mutator_speed, gc_speed);
4047   }
4048   return result;
4049 }
4050 
4051 
OldGenerationMutatorUtilization()4052 double Heap::OldGenerationMutatorUtilization() {
4053   double mutator_speed = static_cast<double>(
4054       tracer()->OldGenerationAllocationThroughputInBytesPerMillisecond());
4055   double gc_speed = static_cast<double>(
4056       tracer()->CombinedMarkCompactSpeedInBytesPerMillisecond());
4057   double result = ComputeMutatorUtilization(mutator_speed, gc_speed);
4058   if (FLAG_trace_mutator_utilization) {
4059     PrintIsolate(isolate(),
4060                  "Old generation mutator utilization = %.3f ("
4061                  "mutator_speed=%.f, gc_speed=%.f)\n",
4062                  result, mutator_speed, gc_speed);
4063   }
4064   return result;
4065 }
4066 
4067 
HasLowYoungGenerationAllocationRate()4068 bool Heap::HasLowYoungGenerationAllocationRate() {
4069   const double high_mutator_utilization = 0.993;
4070   return YoungGenerationMutatorUtilization() > high_mutator_utilization;
4071 }
4072 
4073 
HasLowOldGenerationAllocationRate()4074 bool Heap::HasLowOldGenerationAllocationRate() {
4075   const double high_mutator_utilization = 0.993;
4076   return OldGenerationMutatorUtilization() > high_mutator_utilization;
4077 }
4078 
4079 
HasLowAllocationRate()4080 bool Heap::HasLowAllocationRate() {
4081   return HasLowYoungGenerationAllocationRate() &&
4082          HasLowOldGenerationAllocationRate();
4083 }
4084 
4085 
HasHighFragmentation()4086 bool Heap::HasHighFragmentation() {
4087   intptr_t used = PromotedSpaceSizeOfObjects();
4088   intptr_t committed = CommittedOldGenerationMemory();
4089   return HasHighFragmentation(used, committed);
4090 }
4091 
4092 
HasHighFragmentation(intptr_t used,intptr_t committed)4093 bool Heap::HasHighFragmentation(intptr_t used, intptr_t committed) {
4094   const intptr_t kSlack = 16 * MB;
4095   // Fragmentation is high if committed > 2 * used + kSlack.
4096   // Rewrite the exression to avoid overflow.
4097   return committed - used > used + kSlack;
4098 }
4099 
4100 
ReduceNewSpaceSize()4101 void Heap::ReduceNewSpaceSize() {
4102   // TODO(ulan): Unify this constant with the similar constant in
4103   // GCIdleTimeHandler once the change is merged to 4.5.
4104   static const size_t kLowAllocationThroughput = 1000;
4105   const size_t allocation_throughput =
4106       tracer()->CurrentAllocationThroughputInBytesPerMillisecond();
4107 
4108   if (FLAG_predictable) return;
4109 
4110   if (ShouldReduceMemory() ||
4111       ((allocation_throughput != 0) &&
4112        (allocation_throughput < kLowAllocationThroughput))) {
4113     new_space_.Shrink();
4114     UncommitFromSpace();
4115   }
4116 }
4117 
4118 
FinalizeIncrementalMarkingIfComplete(const char * comment)4119 void Heap::FinalizeIncrementalMarkingIfComplete(const char* comment) {
4120   if (incremental_marking()->IsMarking() &&
4121       (incremental_marking()->IsReadyToOverApproximateWeakClosure() ||
4122        (!incremental_marking()->finalize_marking_completed() &&
4123         mark_compact_collector()->marking_deque()->IsEmpty()))) {
4124     FinalizeIncrementalMarking(comment);
4125   } else if (incremental_marking()->IsComplete() ||
4126              (mark_compact_collector()->marking_deque()->IsEmpty())) {
4127     CollectAllGarbage(current_gc_flags_, comment);
4128   }
4129 }
4130 
4131 
TryFinalizeIdleIncrementalMarking(double idle_time_in_ms)4132 bool Heap::TryFinalizeIdleIncrementalMarking(double idle_time_in_ms) {
4133   size_t size_of_objects = static_cast<size_t>(SizeOfObjects());
4134   size_t final_incremental_mark_compact_speed_in_bytes_per_ms =
4135       static_cast<size_t>(
4136           tracer()->FinalIncrementalMarkCompactSpeedInBytesPerMillisecond());
4137   if (incremental_marking()->IsReadyToOverApproximateWeakClosure() ||
4138       (!incremental_marking()->finalize_marking_completed() &&
4139        mark_compact_collector()->marking_deque()->IsEmpty() &&
4140        gc_idle_time_handler_->ShouldDoOverApproximateWeakClosure(
4141            static_cast<size_t>(idle_time_in_ms)))) {
4142     FinalizeIncrementalMarking(
4143         "Idle notification: finalize incremental marking");
4144     return true;
4145   } else if (incremental_marking()->IsComplete() ||
4146              (mark_compact_collector()->marking_deque()->IsEmpty() &&
4147               gc_idle_time_handler_->ShouldDoFinalIncrementalMarkCompact(
4148                   static_cast<size_t>(idle_time_in_ms), size_of_objects,
4149                   final_incremental_mark_compact_speed_in_bytes_per_ms))) {
4150     CollectAllGarbage(current_gc_flags_,
4151                       "idle notification: finalize incremental marking");
4152     return true;
4153   }
4154   return false;
4155 }
4156 
4157 
ComputeHeapState()4158 GCIdleTimeHeapState Heap::ComputeHeapState() {
4159   GCIdleTimeHeapState heap_state;
4160   heap_state.contexts_disposed = contexts_disposed_;
4161   heap_state.contexts_disposal_rate =
4162       tracer()->ContextDisposalRateInMilliseconds();
4163   heap_state.size_of_objects = static_cast<size_t>(SizeOfObjects());
4164   heap_state.incremental_marking_stopped = incremental_marking()->IsStopped();
4165   return heap_state;
4166 }
4167 
4168 
PerformIdleTimeAction(GCIdleTimeAction action,GCIdleTimeHeapState heap_state,double deadline_in_ms)4169 bool Heap::PerformIdleTimeAction(GCIdleTimeAction action,
4170                                  GCIdleTimeHeapState heap_state,
4171                                  double deadline_in_ms) {
4172   bool result = false;
4173   switch (action.type) {
4174     case DONE:
4175       result = true;
4176       break;
4177     case DO_INCREMENTAL_STEP: {
4178       if (incremental_marking()->incremental_marking_job()->IdleTaskPending()) {
4179         result = true;
4180       } else {
4181         incremental_marking()
4182             ->incremental_marking_job()
4183             ->NotifyIdleTaskProgress();
4184         result = IncrementalMarkingJob::IdleTask::Step(this, deadline_in_ms) ==
4185                  IncrementalMarkingJob::IdleTask::kDone;
4186       }
4187       break;
4188     }
4189     case DO_FULL_GC: {
4190       DCHECK(contexts_disposed_ > 0);
4191       HistogramTimerScope scope(isolate_->counters()->gc_context());
4192       CollectAllGarbage(kNoGCFlags, "idle notification: contexts disposed");
4193       break;
4194     }
4195     case DO_NOTHING:
4196       break;
4197   }
4198 
4199   return result;
4200 }
4201 
4202 
IdleNotificationEpilogue(GCIdleTimeAction action,GCIdleTimeHeapState heap_state,double start_ms,double deadline_in_ms)4203 void Heap::IdleNotificationEpilogue(GCIdleTimeAction action,
4204                                     GCIdleTimeHeapState heap_state,
4205                                     double start_ms, double deadline_in_ms) {
4206   double idle_time_in_ms = deadline_in_ms - start_ms;
4207   double current_time = MonotonicallyIncreasingTimeInMs();
4208   last_idle_notification_time_ = current_time;
4209   double deadline_difference = deadline_in_ms - current_time;
4210 
4211   contexts_disposed_ = 0;
4212 
4213   isolate()->counters()->gc_idle_time_allotted_in_ms()->AddSample(
4214       static_cast<int>(idle_time_in_ms));
4215 
4216   if (deadline_in_ms - start_ms >
4217       GCIdleTimeHandler::kMaxFrameRenderingIdleTime) {
4218     int committed_memory = static_cast<int>(CommittedMemory() / KB);
4219     int used_memory = static_cast<int>(heap_state.size_of_objects / KB);
4220     isolate()->counters()->aggregated_memory_heap_committed()->AddSample(
4221         start_ms, committed_memory);
4222     isolate()->counters()->aggregated_memory_heap_used()->AddSample(
4223         start_ms, used_memory);
4224   }
4225 
4226   if (deadline_difference >= 0) {
4227     if (action.type != DONE && action.type != DO_NOTHING) {
4228       isolate()->counters()->gc_idle_time_limit_undershot()->AddSample(
4229           static_cast<int>(deadline_difference));
4230     }
4231   } else {
4232     isolate()->counters()->gc_idle_time_limit_overshot()->AddSample(
4233         static_cast<int>(-deadline_difference));
4234   }
4235 
4236   if ((FLAG_trace_idle_notification && action.type > DO_NOTHING) ||
4237       FLAG_trace_idle_notification_verbose) {
4238     PrintIsolate(isolate_, "%8.0f ms: ", isolate()->time_millis_since_init());
4239     PrintF(
4240         "Idle notification: requested idle time %.2f ms, used idle time %.2f "
4241         "ms, deadline usage %.2f ms [",
4242         idle_time_in_ms, idle_time_in_ms - deadline_difference,
4243         deadline_difference);
4244     action.Print();
4245     PrintF("]");
4246     if (FLAG_trace_idle_notification_verbose) {
4247       PrintF("[");
4248       heap_state.Print();
4249       PrintF("]");
4250     }
4251     PrintF("\n");
4252   }
4253 }
4254 
4255 
MonotonicallyIncreasingTimeInMs()4256 double Heap::MonotonicallyIncreasingTimeInMs() {
4257   return V8::GetCurrentPlatform()->MonotonicallyIncreasingTime() *
4258          static_cast<double>(base::Time::kMillisecondsPerSecond);
4259 }
4260 
4261 
IdleNotification(int idle_time_in_ms)4262 bool Heap::IdleNotification(int idle_time_in_ms) {
4263   return IdleNotification(
4264       V8::GetCurrentPlatform()->MonotonicallyIncreasingTime() +
4265       (static_cast<double>(idle_time_in_ms) /
4266        static_cast<double>(base::Time::kMillisecondsPerSecond)));
4267 }
4268 
4269 
IdleNotification(double deadline_in_seconds)4270 bool Heap::IdleNotification(double deadline_in_seconds) {
4271   CHECK(HasBeenSetUp());
4272   double deadline_in_ms =
4273       deadline_in_seconds *
4274       static_cast<double>(base::Time::kMillisecondsPerSecond);
4275   HistogramTimerScope idle_notification_scope(
4276       isolate_->counters()->gc_idle_notification());
4277   double start_ms = MonotonicallyIncreasingTimeInMs();
4278   double idle_time_in_ms = deadline_in_ms - start_ms;
4279 
4280   tracer()->SampleAllocation(start_ms, NewSpaceAllocationCounter(),
4281                              OldGenerationAllocationCounter());
4282 
4283   GCIdleTimeHeapState heap_state = ComputeHeapState();
4284 
4285   GCIdleTimeAction action =
4286       gc_idle_time_handler_->Compute(idle_time_in_ms, heap_state);
4287 
4288   bool result = PerformIdleTimeAction(action, heap_state, deadline_in_ms);
4289 
4290   IdleNotificationEpilogue(action, heap_state, start_ms, deadline_in_ms);
4291   return result;
4292 }
4293 
4294 
RecentIdleNotificationHappened()4295 bool Heap::RecentIdleNotificationHappened() {
4296   return (last_idle_notification_time_ +
4297           GCIdleTimeHandler::kMaxScheduledIdleTime) >
4298          MonotonicallyIncreasingTimeInMs();
4299 }
4300 
4301 
4302 #ifdef DEBUG
4303 
Print()4304 void Heap::Print() {
4305   if (!HasBeenSetUp()) return;
4306   isolate()->PrintStack(stdout);
4307   AllSpaces spaces(this);
4308   for (Space* space = spaces.next(); space != NULL; space = spaces.next()) {
4309     space->Print();
4310   }
4311 }
4312 
4313 
ReportCodeStatistics(const char * title)4314 void Heap::ReportCodeStatistics(const char* title) {
4315   PrintF(">>>>>> Code Stats (%s) >>>>>>\n", title);
4316   PagedSpace::ResetCodeStatistics(isolate());
4317   // We do not look for code in new space, map space, or old space.  If code
4318   // somehow ends up in those spaces, we would miss it here.
4319   code_space_->CollectCodeStatistics();
4320   lo_space_->CollectCodeStatistics();
4321   PagedSpace::ReportCodeStatistics(isolate());
4322 }
4323 
4324 
4325 // This function expects that NewSpace's allocated objects histogram is
4326 // populated (via a call to CollectStatistics or else as a side effect of a
4327 // just-completed scavenge collection).
ReportHeapStatistics(const char * title)4328 void Heap::ReportHeapStatistics(const char* title) {
4329   USE(title);
4330   PrintF(">>>>>> =============== %s (%d) =============== >>>>>>\n", title,
4331          gc_count_);
4332   PrintF("old_generation_allocation_limit_ %" V8_PTR_PREFIX "d\n",
4333          old_generation_allocation_limit_);
4334 
4335   PrintF("\n");
4336   PrintF("Number of handles : %d\n", HandleScope::NumberOfHandles(isolate_));
4337   isolate_->global_handles()->PrintStats();
4338   PrintF("\n");
4339 
4340   PrintF("Heap statistics : ");
4341   isolate_->memory_allocator()->ReportStatistics();
4342   PrintF("To space : ");
4343   new_space_.ReportStatistics();
4344   PrintF("Old space : ");
4345   old_space_->ReportStatistics();
4346   PrintF("Code space : ");
4347   code_space_->ReportStatistics();
4348   PrintF("Map space : ");
4349   map_space_->ReportStatistics();
4350   PrintF("Large object space : ");
4351   lo_space_->ReportStatistics();
4352   PrintF(">>>>>> ========================================= >>>>>>\n");
4353 }
4354 
4355 #endif  // DEBUG
4356 
Contains(HeapObject * value)4357 bool Heap::Contains(HeapObject* value) { return Contains(value->address()); }
4358 
4359 
Contains(Address addr)4360 bool Heap::Contains(Address addr) {
4361   if (isolate_->memory_allocator()->IsOutsideAllocatedSpace(addr)) return false;
4362   return HasBeenSetUp() &&
4363          (new_space_.ToSpaceContains(addr) || old_space_->Contains(addr) ||
4364           code_space_->Contains(addr) || map_space_->Contains(addr) ||
4365           lo_space_->SlowContains(addr));
4366 }
4367 
4368 
InSpace(HeapObject * value,AllocationSpace space)4369 bool Heap::InSpace(HeapObject* value, AllocationSpace space) {
4370   return InSpace(value->address(), space);
4371 }
4372 
4373 
InSpace(Address addr,AllocationSpace space)4374 bool Heap::InSpace(Address addr, AllocationSpace space) {
4375   if (isolate_->memory_allocator()->IsOutsideAllocatedSpace(addr)) return false;
4376   if (!HasBeenSetUp()) return false;
4377 
4378   switch (space) {
4379     case NEW_SPACE:
4380       return new_space_.ToSpaceContains(addr);
4381     case OLD_SPACE:
4382       return old_space_->Contains(addr);
4383     case CODE_SPACE:
4384       return code_space_->Contains(addr);
4385     case MAP_SPACE:
4386       return map_space_->Contains(addr);
4387     case LO_SPACE:
4388       return lo_space_->SlowContains(addr);
4389   }
4390   UNREACHABLE();
4391   return false;
4392 }
4393 
4394 
IsValidAllocationSpace(AllocationSpace space)4395 bool Heap::IsValidAllocationSpace(AllocationSpace space) {
4396   switch (space) {
4397     case NEW_SPACE:
4398     case OLD_SPACE:
4399     case CODE_SPACE:
4400     case MAP_SPACE:
4401     case LO_SPACE:
4402       return true;
4403     default:
4404       return false;
4405   }
4406 }
4407 
4408 
RootIsImmortalImmovable(int root_index)4409 bool Heap::RootIsImmortalImmovable(int root_index) {
4410   switch (root_index) {
4411 #define IMMORTAL_IMMOVABLE_ROOT(name) case Heap::k##name##RootIndex:
4412     IMMORTAL_IMMOVABLE_ROOT_LIST(IMMORTAL_IMMOVABLE_ROOT)
4413 #undef IMMORTAL_IMMOVABLE_ROOT
4414 #define INTERNALIZED_STRING(name, value) case Heap::k##name##RootIndex:
4415     INTERNALIZED_STRING_LIST(INTERNALIZED_STRING)
4416 #undef INTERNALIZED_STRING
4417 #define STRING_TYPE(NAME, size, name, Name) case Heap::k##Name##MapRootIndex:
4418     STRING_TYPE_LIST(STRING_TYPE)
4419 #undef STRING_TYPE
4420     return true;
4421     default:
4422       return false;
4423   }
4424 }
4425 
4426 
4427 #ifdef VERIFY_HEAP
Verify()4428 void Heap::Verify() {
4429   CHECK(HasBeenSetUp());
4430   HandleScope scope(isolate());
4431 
4432   store_buffer()->Verify();
4433 
4434   if (mark_compact_collector()->sweeping_in_progress()) {
4435     // We have to wait here for the sweeper threads to have an iterable heap.
4436     mark_compact_collector()->EnsureSweepingCompleted();
4437   }
4438 
4439   VerifyPointersVisitor visitor;
4440   IterateRoots(&visitor, VISIT_ONLY_STRONG);
4441 
4442   VerifySmisVisitor smis_visitor;
4443   IterateSmiRoots(&smis_visitor);
4444 
4445   new_space_.Verify();
4446 
4447   old_space_->Verify(&visitor);
4448   map_space_->Verify(&visitor);
4449 
4450   VerifyPointersVisitor no_dirty_regions_visitor;
4451   code_space_->Verify(&no_dirty_regions_visitor);
4452 
4453   lo_space_->Verify();
4454 
4455   mark_compact_collector()->VerifyWeakEmbeddedObjectsInCode();
4456   if (FLAG_omit_map_checks_for_leaf_maps) {
4457     mark_compact_collector()->VerifyOmittedMapChecks();
4458   }
4459 }
4460 #endif
4461 
4462 
ZapFromSpace()4463 void Heap::ZapFromSpace() {
4464   if (!new_space_.IsFromSpaceCommitted()) return;
4465   NewSpacePageIterator it(new_space_.FromSpaceStart(),
4466                           new_space_.FromSpaceEnd());
4467   while (it.has_next()) {
4468     NewSpacePage* page = it.next();
4469     for (Address cursor = page->area_start(), limit = page->area_end();
4470          cursor < limit; cursor += kPointerSize) {
4471       Memory::Address_at(cursor) = kFromSpaceZapValue;
4472     }
4473   }
4474 }
4475 
4476 
IterateAndMarkPointersToFromSpace(HeapObject * object,Address start,Address end,bool record_slots,ObjectSlotCallback callback)4477 void Heap::IterateAndMarkPointersToFromSpace(HeapObject* object, Address start,
4478                                              Address end, bool record_slots,
4479                                              ObjectSlotCallback callback) {
4480   Address slot_address = start;
4481 
4482   while (slot_address < end) {
4483     Object** slot = reinterpret_cast<Object**>(slot_address);
4484     Object* target = *slot;
4485     // If the store buffer becomes overfull we mark pages as being exempt from
4486     // the store buffer.  These pages are scanned to find pointers that point
4487     // to the new space.  In that case we may hit newly promoted objects and
4488     // fix the pointers before the promotion queue gets to them.  Thus the 'if'.
4489     if (target->IsHeapObject()) {
4490       if (Heap::InFromSpace(target)) {
4491         callback(reinterpret_cast<HeapObject**>(slot),
4492                  HeapObject::cast(target));
4493         Object* new_target = *slot;
4494         if (InNewSpace(new_target)) {
4495           SLOW_DCHECK(Heap::InToSpace(new_target));
4496           SLOW_DCHECK(new_target->IsHeapObject());
4497           store_buffer_.EnterDirectlyIntoStoreBuffer(
4498               reinterpret_cast<Address>(slot));
4499         }
4500         SLOW_DCHECK(!MarkCompactCollector::IsOnEvacuationCandidate(new_target));
4501       } else if (record_slots &&
4502                  MarkCompactCollector::IsOnEvacuationCandidate(target)) {
4503         mark_compact_collector()->RecordSlot(object, slot, target);
4504       }
4505     }
4506     slot_address += kPointerSize;
4507   }
4508 }
4509 
4510 
4511 class IteratePointersToFromSpaceVisitor final : public ObjectVisitor {
4512  public:
IteratePointersToFromSpaceVisitor(Heap * heap,HeapObject * target,bool record_slots,ObjectSlotCallback callback)4513   IteratePointersToFromSpaceVisitor(Heap* heap, HeapObject* target,
4514                                     bool record_slots,
4515                                     ObjectSlotCallback callback)
4516       : heap_(heap),
4517         target_(target),
4518         record_slots_(record_slots),
4519         callback_(callback) {}
4520 
VisitPointers(Object ** start,Object ** end)4521   V8_INLINE void VisitPointers(Object** start, Object** end) override {
4522     heap_->IterateAndMarkPointersToFromSpace(
4523         target_, reinterpret_cast<Address>(start),
4524         reinterpret_cast<Address>(end), record_slots_, callback_);
4525   }
4526 
VisitCodeEntry(Address code_entry_slot)4527   V8_INLINE void VisitCodeEntry(Address code_entry_slot) override {}
4528 
4529  private:
4530   Heap* heap_;
4531   HeapObject* target_;
4532   bool record_slots_;
4533   ObjectSlotCallback callback_;
4534 };
4535 
4536 
IteratePointersToFromSpace(HeapObject * target,int size,ObjectSlotCallback callback)4537 void Heap::IteratePointersToFromSpace(HeapObject* target, int size,
4538                                       ObjectSlotCallback callback) {
4539   // We are not collecting slots on new space objects during mutation
4540   // thus we have to scan for pointers to evacuation candidates when we
4541   // promote objects. But we should not record any slots in non-black
4542   // objects. Grey object's slots would be rescanned.
4543   // White object might not survive until the end of collection
4544   // it would be a violation of the invariant to record it's slots.
4545   bool record_slots = false;
4546   if (incremental_marking()->IsCompacting()) {
4547     MarkBit mark_bit = Marking::MarkBitFrom(target);
4548     record_slots = Marking::IsBlack(mark_bit);
4549   }
4550 
4551   IteratePointersToFromSpaceVisitor visitor(this, target, record_slots,
4552                                             callback);
4553   target->IterateBody(target->map()->instance_type(), size, &visitor);
4554 }
4555 
4556 
IterateRoots(ObjectVisitor * v,VisitMode mode)4557 void Heap::IterateRoots(ObjectVisitor* v, VisitMode mode) {
4558   IterateStrongRoots(v, mode);
4559   IterateWeakRoots(v, mode);
4560 }
4561 
4562 
IterateWeakRoots(ObjectVisitor * v,VisitMode mode)4563 void Heap::IterateWeakRoots(ObjectVisitor* v, VisitMode mode) {
4564   v->VisitPointer(reinterpret_cast<Object**>(&roots_[kStringTableRootIndex]));
4565   v->Synchronize(VisitorSynchronization::kStringTable);
4566   if (mode != VISIT_ALL_IN_SCAVENGE && mode != VISIT_ALL_IN_SWEEP_NEWSPACE) {
4567     // Scavenge collections have special processing for this.
4568     external_string_table_.Iterate(v);
4569   }
4570   v->Synchronize(VisitorSynchronization::kExternalStringsTable);
4571 }
4572 
4573 
IterateSmiRoots(ObjectVisitor * v)4574 void Heap::IterateSmiRoots(ObjectVisitor* v) {
4575   // Acquire execution access since we are going to read stack limit values.
4576   ExecutionAccess access(isolate());
4577   v->VisitPointers(&roots_[kSmiRootsStart], &roots_[kRootListLength]);
4578   v->Synchronize(VisitorSynchronization::kSmiRootList);
4579 }
4580 
4581 
IterateStrongRoots(ObjectVisitor * v,VisitMode mode)4582 void Heap::IterateStrongRoots(ObjectVisitor* v, VisitMode mode) {
4583   v->VisitPointers(&roots_[0], &roots_[kStrongRootListLength]);
4584   v->Synchronize(VisitorSynchronization::kStrongRootList);
4585 
4586   isolate_->bootstrapper()->Iterate(v);
4587   v->Synchronize(VisitorSynchronization::kBootstrapper);
4588   isolate_->Iterate(v);
4589   v->Synchronize(VisitorSynchronization::kTop);
4590   Relocatable::Iterate(isolate_, v);
4591   v->Synchronize(VisitorSynchronization::kRelocatable);
4592 
4593   if (isolate_->deoptimizer_data() != NULL) {
4594     isolate_->deoptimizer_data()->Iterate(v);
4595   }
4596   v->Synchronize(VisitorSynchronization::kDebug);
4597   isolate_->compilation_cache()->Iterate(v);
4598   v->Synchronize(VisitorSynchronization::kCompilationCache);
4599 
4600   // Iterate over local handles in handle scopes.
4601   isolate_->handle_scope_implementer()->Iterate(v);
4602   isolate_->IterateDeferredHandles(v);
4603   v->Synchronize(VisitorSynchronization::kHandleScope);
4604 
4605   // Iterate over the builtin code objects and code stubs in the
4606   // heap. Note that it is not necessary to iterate over code objects
4607   // on scavenge collections.
4608   if (mode != VISIT_ALL_IN_SCAVENGE) {
4609     isolate_->builtins()->IterateBuiltins(v);
4610   }
4611   v->Synchronize(VisitorSynchronization::kBuiltins);
4612 
4613   // Iterate over global handles.
4614   switch (mode) {
4615     case VISIT_ONLY_STRONG:
4616       isolate_->global_handles()->IterateStrongRoots(v);
4617       break;
4618     case VISIT_ALL_IN_SCAVENGE:
4619       isolate_->global_handles()->IterateNewSpaceStrongAndDependentRoots(v);
4620       break;
4621     case VISIT_ALL_IN_SWEEP_NEWSPACE:
4622     case VISIT_ALL:
4623       isolate_->global_handles()->IterateAllRoots(v);
4624       break;
4625   }
4626   v->Synchronize(VisitorSynchronization::kGlobalHandles);
4627 
4628   // Iterate over eternal handles.
4629   if (mode == VISIT_ALL_IN_SCAVENGE) {
4630     isolate_->eternal_handles()->IterateNewSpaceRoots(v);
4631   } else {
4632     isolate_->eternal_handles()->IterateAllRoots(v);
4633   }
4634   v->Synchronize(VisitorSynchronization::kEternalHandles);
4635 
4636   // Iterate over pointers being held by inactive threads.
4637   isolate_->thread_manager()->Iterate(v);
4638   v->Synchronize(VisitorSynchronization::kThreadManager);
4639 
4640   // Iterate over other strong roots (currently only identity maps).
4641   for (StrongRootsList* list = strong_roots_list_; list; list = list->next) {
4642     v->VisitPointers(list->start, list->end);
4643   }
4644   v->Synchronize(VisitorSynchronization::kStrongRoots);
4645 
4646   // Iterate over the pointers the Serialization/Deserialization code is
4647   // holding.
4648   // During garbage collection this keeps the partial snapshot cache alive.
4649   // During deserialization of the startup snapshot this creates the partial
4650   // snapshot cache and deserializes the objects it refers to.  During
4651   // serialization this does nothing, since the partial snapshot cache is
4652   // empty.  However the next thing we do is create the partial snapshot,
4653   // filling up the partial snapshot cache with objects it needs as we go.
4654   SerializerDeserializer::Iterate(isolate_, v);
4655   // We don't do a v->Synchronize call here, because in debug mode that will
4656   // output a flag to the snapshot.  However at this point the serializer and
4657   // deserializer are deliberately a little unsynchronized (see above) so the
4658   // checking of the sync flag in the snapshot would fail.
4659 }
4660 
4661 
4662 // TODO(1236194): Since the heap size is configurable on the command line
4663 // and through the API, we should gracefully handle the case that the heap
4664 // size is not big enough to fit all the initial objects.
ConfigureHeap(int max_semi_space_size,int max_old_space_size,int max_executable_size,size_t code_range_size)4665 bool Heap::ConfigureHeap(int max_semi_space_size, int max_old_space_size,
4666                          int max_executable_size, size_t code_range_size) {
4667   if (HasBeenSetUp()) return false;
4668 
4669   // Overwrite default configuration.
4670   if (max_semi_space_size > 0) {
4671     max_semi_space_size_ = max_semi_space_size * MB;
4672   }
4673   if (max_old_space_size > 0) {
4674     max_old_generation_size_ = static_cast<intptr_t>(max_old_space_size) * MB;
4675   }
4676   if (max_executable_size > 0) {
4677     max_executable_size_ = static_cast<intptr_t>(max_executable_size) * MB;
4678   }
4679 
4680   // If max space size flags are specified overwrite the configuration.
4681   if (FLAG_max_semi_space_size > 0) {
4682     max_semi_space_size_ = FLAG_max_semi_space_size * MB;
4683   }
4684   if (FLAG_max_old_space_size > 0) {
4685     max_old_generation_size_ =
4686         static_cast<intptr_t>(FLAG_max_old_space_size) * MB;
4687   }
4688   if (FLAG_max_executable_size > 0) {
4689     max_executable_size_ = static_cast<intptr_t>(FLAG_max_executable_size) * MB;
4690   }
4691 
4692   if (Page::kPageSize > MB) {
4693     max_semi_space_size_ = ROUND_UP(max_semi_space_size_, Page::kPageSize);
4694     max_old_generation_size_ =
4695         ROUND_UP(max_old_generation_size_, Page::kPageSize);
4696     max_executable_size_ = ROUND_UP(max_executable_size_, Page::kPageSize);
4697   }
4698 
4699   if (FLAG_stress_compaction) {
4700     // This will cause more frequent GCs when stressing.
4701     max_semi_space_size_ = Page::kPageSize;
4702   }
4703 
4704   if (isolate()->snapshot_available()) {
4705     // If we are using a snapshot we always reserve the default amount
4706     // of memory for each semispace because code in the snapshot has
4707     // write-barrier code that relies on the size and alignment of new
4708     // space.  We therefore cannot use a larger max semispace size
4709     // than the default reserved semispace size.
4710     if (max_semi_space_size_ > reserved_semispace_size_) {
4711       max_semi_space_size_ = reserved_semispace_size_;
4712       if (FLAG_trace_gc) {
4713         PrintIsolate(isolate_,
4714                      "Max semi-space size cannot be more than %d kbytes\n",
4715                      reserved_semispace_size_ >> 10);
4716       }
4717     }
4718   } else {
4719     // If we are not using snapshots we reserve space for the actual
4720     // max semispace size.
4721     reserved_semispace_size_ = max_semi_space_size_;
4722   }
4723 
4724   // The new space size must be a power of two to support single-bit testing
4725   // for containment.
4726   max_semi_space_size_ =
4727       base::bits::RoundUpToPowerOfTwo32(max_semi_space_size_);
4728   reserved_semispace_size_ =
4729       base::bits::RoundUpToPowerOfTwo32(reserved_semispace_size_);
4730 
4731   if (FLAG_min_semi_space_size > 0) {
4732     int initial_semispace_size = FLAG_min_semi_space_size * MB;
4733     if (initial_semispace_size > max_semi_space_size_) {
4734       initial_semispace_size_ = max_semi_space_size_;
4735       if (FLAG_trace_gc) {
4736         PrintIsolate(isolate_,
4737                      "Min semi-space size cannot be more than the maximum "
4738                      "semi-space size of %d MB\n",
4739                      max_semi_space_size_ / MB);
4740       }
4741     } else {
4742       initial_semispace_size_ =
4743           ROUND_UP(initial_semispace_size, Page::kPageSize);
4744     }
4745   }
4746 
4747   initial_semispace_size_ = Min(initial_semispace_size_, max_semi_space_size_);
4748 
4749   if (FLAG_target_semi_space_size > 0) {
4750     int target_semispace_size = FLAG_target_semi_space_size * MB;
4751     if (target_semispace_size < initial_semispace_size_) {
4752       target_semispace_size_ = initial_semispace_size_;
4753       if (FLAG_trace_gc) {
4754         PrintIsolate(isolate_,
4755                      "Target semi-space size cannot be less than the minimum "
4756                      "semi-space size of %d MB\n",
4757                      initial_semispace_size_ / MB);
4758       }
4759     } else if (target_semispace_size > max_semi_space_size_) {
4760       target_semispace_size_ = max_semi_space_size_;
4761       if (FLAG_trace_gc) {
4762         PrintIsolate(isolate_,
4763                      "Target semi-space size cannot be less than the maximum "
4764                      "semi-space size of %d MB\n",
4765                      max_semi_space_size_ / MB);
4766       }
4767     } else {
4768       target_semispace_size_ = ROUND_UP(target_semispace_size, Page::kPageSize);
4769     }
4770   }
4771 
4772   target_semispace_size_ = Max(initial_semispace_size_, target_semispace_size_);
4773 
4774   if (FLAG_semi_space_growth_factor < 2) {
4775     FLAG_semi_space_growth_factor = 2;
4776   }
4777 
4778   // The old generation is paged and needs at least one page for each space.
4779   int paged_space_count = LAST_PAGED_SPACE - FIRST_PAGED_SPACE + 1;
4780   max_old_generation_size_ =
4781       Max(static_cast<intptr_t>(paged_space_count * Page::kPageSize),
4782           max_old_generation_size_);
4783 
4784   // The max executable size must be less than or equal to the max old
4785   // generation size.
4786   if (max_executable_size_ > max_old_generation_size_) {
4787     max_executable_size_ = max_old_generation_size_;
4788   }
4789 
4790   if (FLAG_initial_old_space_size > 0) {
4791     initial_old_generation_size_ = FLAG_initial_old_space_size * MB;
4792   } else {
4793     initial_old_generation_size_ =
4794         max_old_generation_size_ / kInitalOldGenerationLimitFactor;
4795   }
4796   old_generation_allocation_limit_ = initial_old_generation_size_;
4797 
4798   // We rely on being able to allocate new arrays in paged spaces.
4799   DCHECK(Page::kMaxRegularHeapObjectSize >=
4800          (JSArray::kSize +
4801           FixedArray::SizeFor(JSArray::kInitialMaxFastElementArray) +
4802           AllocationMemento::kSize));
4803 
4804   code_range_size_ = code_range_size * MB;
4805 
4806   configured_ = true;
4807   return true;
4808 }
4809 
4810 
AddToRingBuffer(const char * string)4811 void Heap::AddToRingBuffer(const char* string) {
4812   size_t first_part =
4813       Min(strlen(string), kTraceRingBufferSize - ring_buffer_end_);
4814   memcpy(trace_ring_buffer_ + ring_buffer_end_, string, first_part);
4815   ring_buffer_end_ += first_part;
4816   if (first_part < strlen(string)) {
4817     ring_buffer_full_ = true;
4818     size_t second_part = strlen(string) - first_part;
4819     memcpy(trace_ring_buffer_, string + first_part, second_part);
4820     ring_buffer_end_ = second_part;
4821   }
4822 }
4823 
4824 
GetFromRingBuffer(char * buffer)4825 void Heap::GetFromRingBuffer(char* buffer) {
4826   size_t copied = 0;
4827   if (ring_buffer_full_) {
4828     copied = kTraceRingBufferSize - ring_buffer_end_;
4829     memcpy(buffer, trace_ring_buffer_ + ring_buffer_end_, copied);
4830   }
4831   memcpy(buffer + copied, trace_ring_buffer_, ring_buffer_end_);
4832 }
4833 
4834 
ConfigureHeapDefault()4835 bool Heap::ConfigureHeapDefault() { return ConfigureHeap(0, 0, 0, 0); }
4836 
4837 
RecordStats(HeapStats * stats,bool take_snapshot)4838 void Heap::RecordStats(HeapStats* stats, bool take_snapshot) {
4839   *stats->start_marker = HeapStats::kStartMarker;
4840   *stats->end_marker = HeapStats::kEndMarker;
4841   *stats->new_space_size = new_space_.SizeAsInt();
4842   *stats->new_space_capacity = static_cast<int>(new_space_.Capacity());
4843   *stats->old_space_size = old_space_->SizeOfObjects();
4844   *stats->old_space_capacity = old_space_->Capacity();
4845   *stats->code_space_size = code_space_->SizeOfObjects();
4846   *stats->code_space_capacity = code_space_->Capacity();
4847   *stats->map_space_size = map_space_->SizeOfObjects();
4848   *stats->map_space_capacity = map_space_->Capacity();
4849   *stats->lo_space_size = lo_space_->Size();
4850   isolate_->global_handles()->RecordStats(stats);
4851   *stats->memory_allocator_size = isolate()->memory_allocator()->Size();
4852   *stats->memory_allocator_capacity =
4853       isolate()->memory_allocator()->Size() +
4854       isolate()->memory_allocator()->Available();
4855   *stats->os_error = base::OS::GetLastError();
4856   isolate()->memory_allocator()->Available();
4857   if (take_snapshot) {
4858     HeapIterator iterator(this);
4859     for (HeapObject* obj = iterator.next(); obj != NULL;
4860          obj = iterator.next()) {
4861       InstanceType type = obj->map()->instance_type();
4862       DCHECK(0 <= type && type <= LAST_TYPE);
4863       stats->objects_per_type[type]++;
4864       stats->size_per_type[type] += obj->Size();
4865     }
4866   }
4867   if (stats->last_few_messages != NULL)
4868     GetFromRingBuffer(stats->last_few_messages);
4869   if (stats->js_stacktrace != NULL) {
4870     FixedStringAllocator fixed(stats->js_stacktrace, kStacktraceBufferSize - 1);
4871     StringStream accumulator(&fixed, StringStream::kPrintObjectConcise);
4872     if (gc_state() == Heap::NOT_IN_GC) {
4873       isolate()->PrintStack(&accumulator, Isolate::kPrintStackVerbose);
4874     } else {
4875       accumulator.Add("Cannot get stack trace in GC.");
4876     }
4877   }
4878 }
4879 
4880 
PromotedSpaceSizeOfObjects()4881 intptr_t Heap::PromotedSpaceSizeOfObjects() {
4882   return old_space_->SizeOfObjects() + code_space_->SizeOfObjects() +
4883          map_space_->SizeOfObjects() + lo_space_->SizeOfObjects();
4884 }
4885 
4886 
PromotedExternalMemorySize()4887 int64_t Heap::PromotedExternalMemorySize() {
4888   if (amount_of_external_allocated_memory_ <=
4889       amount_of_external_allocated_memory_at_last_global_gc_)
4890     return 0;
4891   return amount_of_external_allocated_memory_ -
4892          amount_of_external_allocated_memory_at_last_global_gc_;
4893 }
4894 
4895 
4896 const double Heap::kMinHeapGrowingFactor = 1.1;
4897 const double Heap::kMaxHeapGrowingFactor = 4.0;
4898 const double Heap::kMaxHeapGrowingFactorMemoryConstrained = 2.0;
4899 const double Heap::kMaxHeapGrowingFactorIdle = 1.5;
4900 const double Heap::kTargetMutatorUtilization = 0.97;
4901 
4902 
4903 // Given GC speed in bytes per ms, the allocation throughput in bytes per ms
4904 // (mutator speed), this function returns the heap growing factor that will
4905 // achieve the kTargetMutatorUtilisation if the GC speed and the mutator speed
4906 // remain the same until the next GC.
4907 //
4908 // For a fixed time-frame T = TM + TG, the mutator utilization is the ratio
4909 // TM / (TM + TG), where TM is the time spent in the mutator and TG is the
4910 // time spent in the garbage collector.
4911 //
4912 // Let MU be kTargetMutatorUtilisation, the desired mutator utilization for the
4913 // time-frame from the end of the current GC to the end of the next GC. Based
4914 // on the MU we can compute the heap growing factor F as
4915 //
4916 // F = R * (1 - MU) / (R * (1 - MU) - MU), where R = gc_speed / mutator_speed.
4917 //
4918 // This formula can be derived as follows.
4919 //
4920 // F = Limit / Live by definition, where the Limit is the allocation limit,
4921 // and the Live is size of live objects.
4922 // Let’s assume that we already know the Limit. Then:
4923 //   TG = Limit / gc_speed
4924 //   TM = (TM + TG) * MU, by definition of MU.
4925 //   TM = TG * MU / (1 - MU)
4926 //   TM = Limit *  MU / (gc_speed * (1 - MU))
4927 // On the other hand, if the allocation throughput remains constant:
4928 //   Limit = Live + TM * allocation_throughput = Live + TM * mutator_speed
4929 // Solving it for TM, we get
4930 //   TM = (Limit - Live) / mutator_speed
4931 // Combining the two equation for TM:
4932 //   (Limit - Live) / mutator_speed = Limit * MU / (gc_speed * (1 - MU))
4933 //   (Limit - Live) = Limit * MU * mutator_speed / (gc_speed * (1 - MU))
4934 // substitute R = gc_speed / mutator_speed
4935 //   (Limit - Live) = Limit * MU  / (R * (1 - MU))
4936 // substitute F = Limit / Live
4937 //   F - 1 = F * MU  / (R * (1 - MU))
4938 //   F - F * MU / (R * (1 - MU)) = 1
4939 //   F * (1 - MU / (R * (1 - MU))) = 1
4940 //   F * (R * (1 - MU) - MU) / (R * (1 - MU)) = 1
4941 //   F = R * (1 - MU) / (R * (1 - MU) - MU)
HeapGrowingFactor(double gc_speed,double mutator_speed)4942 double Heap::HeapGrowingFactor(double gc_speed, double mutator_speed) {
4943   if (gc_speed == 0 || mutator_speed == 0) return kMaxHeapGrowingFactor;
4944 
4945   const double speed_ratio = gc_speed / mutator_speed;
4946   const double mu = kTargetMutatorUtilization;
4947 
4948   const double a = speed_ratio * (1 - mu);
4949   const double b = speed_ratio * (1 - mu) - mu;
4950 
4951   // The factor is a / b, but we need to check for small b first.
4952   double factor =
4953       (a < b * kMaxHeapGrowingFactor) ? a / b : kMaxHeapGrowingFactor;
4954   factor = Min(factor, kMaxHeapGrowingFactor);
4955   factor = Max(factor, kMinHeapGrowingFactor);
4956   return factor;
4957 }
4958 
4959 
CalculateOldGenerationAllocationLimit(double factor,intptr_t old_gen_size)4960 intptr_t Heap::CalculateOldGenerationAllocationLimit(double factor,
4961                                                      intptr_t old_gen_size) {
4962   CHECK(factor > 1.0);
4963   CHECK(old_gen_size > 0);
4964   intptr_t limit = static_cast<intptr_t>(old_gen_size * factor);
4965   limit = Max(limit, old_gen_size + kMinimumOldGenerationAllocationLimit);
4966   limit += new_space_.Capacity();
4967   intptr_t halfway_to_the_max = (old_gen_size + max_old_generation_size_) / 2;
4968   return Min(limit, halfway_to_the_max);
4969 }
4970 
4971 
SetOldGenerationAllocationLimit(intptr_t old_gen_size,double gc_speed,double mutator_speed)4972 void Heap::SetOldGenerationAllocationLimit(intptr_t old_gen_size,
4973                                            double gc_speed,
4974                                            double mutator_speed) {
4975   const double kConservativeHeapGrowingFactor = 1.3;
4976 
4977   double factor = HeapGrowingFactor(gc_speed, mutator_speed);
4978 
4979   if (FLAG_trace_gc_verbose) {
4980     PrintIsolate(isolate_,
4981                  "Heap growing factor %.1f based on mu=%.3f, speed_ratio=%.f "
4982                  "(gc=%.f, mutator=%.f)\n",
4983                  factor, kTargetMutatorUtilization, gc_speed / mutator_speed,
4984                  gc_speed, mutator_speed);
4985   }
4986 
4987   // We set the old generation growing factor to 2 to grow the heap slower on
4988   // memory-constrained devices.
4989   if (max_old_generation_size_ <= kMaxOldSpaceSizeMediumMemoryDevice ||
4990       FLAG_optimize_for_size) {
4991     factor = Min(factor, kMaxHeapGrowingFactorMemoryConstrained);
4992   }
4993 
4994   if (memory_reducer_->ShouldGrowHeapSlowly() || optimize_for_memory_usage_) {
4995     factor = Min(factor, kConservativeHeapGrowingFactor);
4996   }
4997 
4998   if (FLAG_stress_compaction || ShouldReduceMemory()) {
4999     factor = kMinHeapGrowingFactor;
5000   }
5001 
5002   if (FLAG_heap_growing_percent > 0) {
5003     factor = 1.0 + FLAG_heap_growing_percent / 100.0;
5004   }
5005 
5006   old_generation_allocation_limit_ =
5007       CalculateOldGenerationAllocationLimit(factor, old_gen_size);
5008 
5009   if (FLAG_trace_gc_verbose) {
5010     PrintIsolate(isolate_, "Grow: old size: %" V8_PTR_PREFIX
5011                            "d KB, new limit: %" V8_PTR_PREFIX "d KB (%.1f)\n",
5012                  old_gen_size / KB, old_generation_allocation_limit_ / KB,
5013                  factor);
5014   }
5015 }
5016 
5017 
DampenOldGenerationAllocationLimit(intptr_t old_gen_size,double gc_speed,double mutator_speed)5018 void Heap::DampenOldGenerationAllocationLimit(intptr_t old_gen_size,
5019                                               double gc_speed,
5020                                               double mutator_speed) {
5021   double factor = HeapGrowingFactor(gc_speed, mutator_speed);
5022   intptr_t limit = CalculateOldGenerationAllocationLimit(factor, old_gen_size);
5023   if (limit < old_generation_allocation_limit_) {
5024     if (FLAG_trace_gc_verbose) {
5025       PrintIsolate(isolate_, "Dampen: old size: %" V8_PTR_PREFIX
5026                              "d KB, old limit: %" V8_PTR_PREFIX
5027                              "d KB, "
5028                              "new limit: %" V8_PTR_PREFIX "d KB (%.1f)\n",
5029                    old_gen_size / KB, old_generation_allocation_limit_ / KB,
5030                    limit / KB, factor);
5031     }
5032     old_generation_allocation_limit_ = limit;
5033   }
5034 }
5035 
5036 
EnableInlineAllocation()5037 void Heap::EnableInlineAllocation() {
5038   if (!inline_allocation_disabled_) return;
5039   inline_allocation_disabled_ = false;
5040 
5041   // Update inline allocation limit for new space.
5042   new_space()->UpdateInlineAllocationLimit(0);
5043 }
5044 
5045 
DisableInlineAllocation()5046 void Heap::DisableInlineAllocation() {
5047   if (inline_allocation_disabled_) return;
5048   inline_allocation_disabled_ = true;
5049 
5050   // Update inline allocation limit for new space.
5051   new_space()->UpdateInlineAllocationLimit(0);
5052 
5053   // Update inline allocation limit for old spaces.
5054   PagedSpaces spaces(this);
5055   for (PagedSpace* space = spaces.next(); space != NULL;
5056        space = spaces.next()) {
5057     space->EmptyAllocationInfo();
5058   }
5059 }
5060 
5061 
5062 V8_DECLARE_ONCE(initialize_gc_once);
5063 
InitializeGCOnce()5064 static void InitializeGCOnce() {
5065   Scavenger::Initialize();
5066   StaticScavengeVisitor::Initialize();
5067   MarkCompactCollector::Initialize();
5068 }
5069 
5070 
SetUp()5071 bool Heap::SetUp() {
5072 #ifdef DEBUG
5073   allocation_timeout_ = FLAG_gc_interval;
5074 #endif
5075 
5076   // Initialize heap spaces and initial maps and objects. Whenever something
5077   // goes wrong, just return false. The caller should check the results and
5078   // call Heap::TearDown() to release allocated memory.
5079   //
5080   // If the heap is not yet configured (e.g. through the API), configure it.
5081   // Configuration is based on the flags new-space-size (really the semispace
5082   // size) and old-space-size if set or the initial values of semispace_size_
5083   // and old_generation_size_ otherwise.
5084   if (!configured_) {
5085     if (!ConfigureHeapDefault()) return false;
5086   }
5087 
5088   base::CallOnce(&initialize_gc_once, &InitializeGCOnce);
5089 
5090   // Set up memory allocator.
5091   if (!isolate_->memory_allocator()->SetUp(MaxReserved(), MaxExecutableSize()))
5092     return false;
5093 
5094   // Initialize incremental marking.
5095   incremental_marking_ = new IncrementalMarking(this);
5096 
5097   // Set up new space.
5098   if (!new_space_.SetUp(reserved_semispace_size_, max_semi_space_size_)) {
5099     return false;
5100   }
5101   new_space_top_after_last_gc_ = new_space()->top();
5102 
5103   // Initialize old space.
5104   old_space_ = new OldSpace(this, OLD_SPACE, NOT_EXECUTABLE);
5105   if (old_space_ == NULL) return false;
5106   if (!old_space_->SetUp()) return false;
5107 
5108   if (!isolate_->code_range()->SetUp(code_range_size_)) return false;
5109 
5110   // Initialize the code space, set its maximum capacity to the old
5111   // generation size. It needs executable memory.
5112   code_space_ = new OldSpace(this, CODE_SPACE, EXECUTABLE);
5113   if (code_space_ == NULL) return false;
5114   if (!code_space_->SetUp()) return false;
5115 
5116   // Initialize map space.
5117   map_space_ = new MapSpace(this, MAP_SPACE);
5118   if (map_space_ == NULL) return false;
5119   if (!map_space_->SetUp()) return false;
5120 
5121   // The large object code space may contain code or data.  We set the memory
5122   // to be non-executable here for safety, but this means we need to enable it
5123   // explicitly when allocating large code objects.
5124   lo_space_ = new LargeObjectSpace(this, LO_SPACE);
5125   if (lo_space_ == NULL) return false;
5126   if (!lo_space_->SetUp()) return false;
5127 
5128   // Set up the seed that is used to randomize the string hash function.
5129   DCHECK(hash_seed() == 0);
5130   if (FLAG_randomize_hashes) {
5131     if (FLAG_hash_seed == 0) {
5132       int rnd = isolate()->random_number_generator()->NextInt();
5133       set_hash_seed(Smi::FromInt(rnd & Name::kHashBitMask));
5134     } else {
5135       set_hash_seed(Smi::FromInt(FLAG_hash_seed));
5136     }
5137   }
5138 
5139   for (int i = 0; i < static_cast<int>(v8::Isolate::kUseCounterFeatureCount);
5140        i++) {
5141     deferred_counters_[i] = 0;
5142   }
5143 
5144   tracer_ = new GCTracer(this);
5145 
5146   scavenge_collector_ = new Scavenger(this);
5147 
5148   mark_compact_collector_ = new MarkCompactCollector(this);
5149 
5150   gc_idle_time_handler_ = new GCIdleTimeHandler();
5151 
5152   memory_reducer_ = new MemoryReducer(this);
5153 
5154   object_stats_ = new ObjectStats(this);
5155   object_stats_->ClearObjectStats(true);
5156 
5157   scavenge_job_ = new ScavengeJob();
5158 
5159   array_buffer_tracker_ = new ArrayBufferTracker(this);
5160 
5161   LOG(isolate_, IntPtrTEvent("heap-capacity", Capacity()));
5162   LOG(isolate_, IntPtrTEvent("heap-available", Available()));
5163 
5164   store_buffer()->SetUp();
5165 
5166   mark_compact_collector()->SetUp();
5167 
5168   idle_scavenge_observer_ = new IdleScavengeObserver(
5169       *this, ScavengeJob::kBytesAllocatedBeforeNextIdleTask);
5170   new_space()->AddInlineAllocationObserver(idle_scavenge_observer_);
5171 
5172   return true;
5173 }
5174 
5175 
CreateHeapObjects()5176 bool Heap::CreateHeapObjects() {
5177   // Create initial maps.
5178   if (!CreateInitialMaps()) return false;
5179   CreateApiObjects();
5180 
5181   // Create initial objects
5182   CreateInitialObjects();
5183   CHECK_EQ(0u, gc_count_);
5184 
5185   set_native_contexts_list(undefined_value());
5186   set_allocation_sites_list(undefined_value());
5187 
5188   return true;
5189 }
5190 
5191 
SetStackLimits()5192 void Heap::SetStackLimits() {
5193   DCHECK(isolate_ != NULL);
5194   DCHECK(isolate_ == isolate());
5195   // On 64 bit machines, pointers are generally out of range of Smis.  We write
5196   // something that looks like an out of range Smi to the GC.
5197 
5198   // Set up the special root array entries containing the stack limits.
5199   // These are actually addresses, but the tag makes the GC ignore it.
5200   roots_[kStackLimitRootIndex] = reinterpret_cast<Object*>(
5201       (isolate_->stack_guard()->jslimit() & ~kSmiTagMask) | kSmiTag);
5202   roots_[kRealStackLimitRootIndex] = reinterpret_cast<Object*>(
5203       (isolate_->stack_guard()->real_jslimit() & ~kSmiTagMask) | kSmiTag);
5204 }
5205 
5206 
PrintAlloctionsHash()5207 void Heap::PrintAlloctionsHash() {
5208   uint32_t hash = StringHasher::GetHashCore(raw_allocations_hash_);
5209   PrintF("\n### Allocations = %u, hash = 0x%08x\n", allocations_count(), hash);
5210 }
5211 
5212 
NotifyDeserializationComplete()5213 void Heap::NotifyDeserializationComplete() {
5214   deserialization_complete_ = true;
5215 #ifdef DEBUG
5216   // All pages right after bootstrapping must be marked as never-evacuate.
5217   PagedSpaces spaces(this);
5218   for (PagedSpace* s = spaces.next(); s != NULL; s = spaces.next()) {
5219     PageIterator it(s);
5220     while (it.has_next()) CHECK(it.next()->NeverEvacuate());
5221   }
5222 #endif  // DEBUG
5223 }
5224 
5225 
TearDown()5226 void Heap::TearDown() {
5227 #ifdef VERIFY_HEAP
5228   if (FLAG_verify_heap) {
5229     Verify();
5230   }
5231 #endif
5232 
5233   UpdateMaximumCommitted();
5234 
5235   if (FLAG_print_cumulative_gc_stat) {
5236     PrintF("\n");
5237     PrintF("gc_count=%d ", gc_count_);
5238     PrintF("mark_sweep_count=%d ", ms_count_);
5239     PrintF("max_gc_pause=%.1f ", get_max_gc_pause());
5240     PrintF("total_gc_time=%.1f ", total_gc_time_ms_);
5241     PrintF("min_in_mutator=%.1f ", get_min_in_mutator());
5242     PrintF("max_alive_after_gc=%" V8_PTR_PREFIX "d ", get_max_alive_after_gc());
5243     PrintF("total_marking_time=%.1f ", tracer()->cumulative_marking_duration());
5244     PrintF("total_sweeping_time=%.1f ",
5245            tracer()->cumulative_sweeping_duration());
5246     PrintF("\n\n");
5247   }
5248 
5249   if (FLAG_print_max_heap_committed) {
5250     PrintF("\n");
5251     PrintF("maximum_committed_by_heap=%" V8_PTR_PREFIX "d ",
5252            MaximumCommittedMemory());
5253     PrintF("maximum_committed_by_new_space=%" V8_PTR_PREFIX "d ",
5254            new_space_.MaximumCommittedMemory());
5255     PrintF("maximum_committed_by_old_space=%" V8_PTR_PREFIX "d ",
5256            old_space_->MaximumCommittedMemory());
5257     PrintF("maximum_committed_by_code_space=%" V8_PTR_PREFIX "d ",
5258            code_space_->MaximumCommittedMemory());
5259     PrintF("maximum_committed_by_map_space=%" V8_PTR_PREFIX "d ",
5260            map_space_->MaximumCommittedMemory());
5261     PrintF("maximum_committed_by_lo_space=%" V8_PTR_PREFIX "d ",
5262            lo_space_->MaximumCommittedMemory());
5263     PrintF("\n\n");
5264   }
5265 
5266   if (FLAG_verify_predictable) {
5267     PrintAlloctionsHash();
5268   }
5269 
5270   new_space()->RemoveInlineAllocationObserver(idle_scavenge_observer_);
5271   delete idle_scavenge_observer_;
5272   idle_scavenge_observer_ = nullptr;
5273 
5274   delete scavenge_collector_;
5275   scavenge_collector_ = nullptr;
5276 
5277   if (mark_compact_collector_ != nullptr) {
5278     mark_compact_collector_->TearDown();
5279     delete mark_compact_collector_;
5280     mark_compact_collector_ = nullptr;
5281   }
5282 
5283   delete incremental_marking_;
5284   incremental_marking_ = nullptr;
5285 
5286   delete gc_idle_time_handler_;
5287   gc_idle_time_handler_ = nullptr;
5288 
5289   if (memory_reducer_ != nullptr) {
5290     memory_reducer_->TearDown();
5291     delete memory_reducer_;
5292     memory_reducer_ = nullptr;
5293   }
5294 
5295   delete object_stats_;
5296   object_stats_ = nullptr;
5297 
5298   delete scavenge_job_;
5299   scavenge_job_ = nullptr;
5300 
5301   WaitUntilUnmappingOfFreeChunksCompleted();
5302 
5303   delete array_buffer_tracker_;
5304   array_buffer_tracker_ = nullptr;
5305 
5306   isolate_->global_handles()->TearDown();
5307 
5308   external_string_table_.TearDown();
5309 
5310   delete tracer_;
5311   tracer_ = nullptr;
5312 
5313   new_space_.TearDown();
5314 
5315   if (old_space_ != NULL) {
5316     delete old_space_;
5317     old_space_ = NULL;
5318   }
5319 
5320   if (code_space_ != NULL) {
5321     delete code_space_;
5322     code_space_ = NULL;
5323   }
5324 
5325   if (map_space_ != NULL) {
5326     delete map_space_;
5327     map_space_ = NULL;
5328   }
5329 
5330   if (lo_space_ != NULL) {
5331     lo_space_->TearDown();
5332     delete lo_space_;
5333     lo_space_ = NULL;
5334   }
5335 
5336   store_buffer()->TearDown();
5337 
5338   isolate_->memory_allocator()->TearDown();
5339 
5340   StrongRootsList* next = NULL;
5341   for (StrongRootsList* list = strong_roots_list_; list; list = next) {
5342     next = list->next;
5343     delete list;
5344   }
5345   strong_roots_list_ = NULL;
5346 }
5347 
5348 
AddGCPrologueCallback(v8::Isolate::GCCallback callback,GCType gc_type,bool pass_isolate)5349 void Heap::AddGCPrologueCallback(v8::Isolate::GCCallback callback,
5350                                  GCType gc_type, bool pass_isolate) {
5351   DCHECK(callback != NULL);
5352   GCCallbackPair pair(callback, gc_type, pass_isolate);
5353   DCHECK(!gc_prologue_callbacks_.Contains(pair));
5354   return gc_prologue_callbacks_.Add(pair);
5355 }
5356 
5357 
RemoveGCPrologueCallback(v8::Isolate::GCCallback callback)5358 void Heap::RemoveGCPrologueCallback(v8::Isolate::GCCallback callback) {
5359   DCHECK(callback != NULL);
5360   for (int i = 0; i < gc_prologue_callbacks_.length(); ++i) {
5361     if (gc_prologue_callbacks_[i].callback == callback) {
5362       gc_prologue_callbacks_.Remove(i);
5363       return;
5364     }
5365   }
5366   UNREACHABLE();
5367 }
5368 
5369 
AddGCEpilogueCallback(v8::Isolate::GCCallback callback,GCType gc_type,bool pass_isolate)5370 void Heap::AddGCEpilogueCallback(v8::Isolate::GCCallback callback,
5371                                  GCType gc_type, bool pass_isolate) {
5372   DCHECK(callback != NULL);
5373   GCCallbackPair pair(callback, gc_type, pass_isolate);
5374   DCHECK(!gc_epilogue_callbacks_.Contains(pair));
5375   return gc_epilogue_callbacks_.Add(pair);
5376 }
5377 
5378 
RemoveGCEpilogueCallback(v8::Isolate::GCCallback callback)5379 void Heap::RemoveGCEpilogueCallback(v8::Isolate::GCCallback callback) {
5380   DCHECK(callback != NULL);
5381   for (int i = 0; i < gc_epilogue_callbacks_.length(); ++i) {
5382     if (gc_epilogue_callbacks_[i].callback == callback) {
5383       gc_epilogue_callbacks_.Remove(i);
5384       return;
5385     }
5386   }
5387   UNREACHABLE();
5388 }
5389 
5390 
5391 // TODO(ishell): Find a better place for this.
AddWeakObjectToCodeDependency(Handle<HeapObject> obj,Handle<DependentCode> dep)5392 void Heap::AddWeakObjectToCodeDependency(Handle<HeapObject> obj,
5393                                          Handle<DependentCode> dep) {
5394   DCHECK(!InNewSpace(*obj));
5395   DCHECK(!InNewSpace(*dep));
5396   Handle<WeakHashTable> table(weak_object_to_code_table(), isolate());
5397   table = WeakHashTable::Put(table, obj, dep);
5398   if (*table != weak_object_to_code_table())
5399     set_weak_object_to_code_table(*table);
5400   DCHECK_EQ(*dep, LookupWeakObjectToCodeDependency(obj));
5401 }
5402 
5403 
LookupWeakObjectToCodeDependency(Handle<HeapObject> obj)5404 DependentCode* Heap::LookupWeakObjectToCodeDependency(Handle<HeapObject> obj) {
5405   Object* dep = weak_object_to_code_table()->Lookup(obj);
5406   if (dep->IsDependentCode()) return DependentCode::cast(dep);
5407   return DependentCode::cast(empty_fixed_array());
5408 }
5409 
5410 
AddRetainedMap(Handle<Map> map)5411 void Heap::AddRetainedMap(Handle<Map> map) {
5412   Handle<WeakCell> cell = Map::WeakCellForMap(map);
5413   Handle<ArrayList> array(retained_maps(), isolate());
5414   if (array->IsFull()) {
5415     CompactRetainedMaps(*array);
5416   }
5417   array = ArrayList::Add(
5418       array, cell, handle(Smi::FromInt(FLAG_retain_maps_for_n_gc), isolate()),
5419       ArrayList::kReloadLengthAfterAllocation);
5420   if (*array != retained_maps()) {
5421     set_retained_maps(*array);
5422   }
5423 }
5424 
5425 
CompactRetainedMaps(ArrayList * retained_maps)5426 void Heap::CompactRetainedMaps(ArrayList* retained_maps) {
5427   DCHECK_EQ(retained_maps, this->retained_maps());
5428   int length = retained_maps->Length();
5429   int new_length = 0;
5430   int new_number_of_disposed_maps = 0;
5431   // This loop compacts the array by removing cleared weak cells.
5432   for (int i = 0; i < length; i += 2) {
5433     DCHECK(retained_maps->Get(i)->IsWeakCell());
5434     WeakCell* cell = WeakCell::cast(retained_maps->Get(i));
5435     Object* age = retained_maps->Get(i + 1);
5436     if (cell->cleared()) continue;
5437     if (i != new_length) {
5438       retained_maps->Set(new_length, cell);
5439       retained_maps->Set(new_length + 1, age);
5440     }
5441     if (i < number_of_disposed_maps_) {
5442       new_number_of_disposed_maps += 2;
5443     }
5444     new_length += 2;
5445   }
5446   number_of_disposed_maps_ = new_number_of_disposed_maps;
5447   Object* undefined = undefined_value();
5448   for (int i = new_length; i < length; i++) {
5449     retained_maps->Clear(i, undefined);
5450   }
5451   if (new_length != length) retained_maps->SetLength(new_length);
5452 }
5453 
5454 
FatalProcessOutOfMemory(const char * location,bool take_snapshot)5455 void Heap::FatalProcessOutOfMemory(const char* location, bool take_snapshot) {
5456   v8::internal::V8::FatalProcessOutOfMemory(location, take_snapshot);
5457 }
5458 
5459 #ifdef DEBUG
5460 
5461 class PrintHandleVisitor : public ObjectVisitor {
5462  public:
VisitPointers(Object ** start,Object ** end)5463   void VisitPointers(Object** start, Object** end) override {
5464     for (Object** p = start; p < end; p++)
5465       PrintF("  handle %p to %p\n", reinterpret_cast<void*>(p),
5466              reinterpret_cast<void*>(*p));
5467   }
5468 };
5469 
5470 
PrintHandles()5471 void Heap::PrintHandles() {
5472   PrintF("Handles:\n");
5473   PrintHandleVisitor v;
5474   isolate_->handle_scope_implementer()->Iterate(&v);
5475 }
5476 
5477 #endif
5478 
5479 class CheckHandleCountVisitor : public ObjectVisitor {
5480  public:
CheckHandleCountVisitor()5481   CheckHandleCountVisitor() : handle_count_(0) {}
~CheckHandleCountVisitor()5482   ~CheckHandleCountVisitor() override {
5483     CHECK(handle_count_ < HandleScope::kCheckHandleThreshold);
5484   }
VisitPointers(Object ** start,Object ** end)5485   void VisitPointers(Object** start, Object** end) override {
5486     handle_count_ += end - start;
5487   }
5488 
5489  private:
5490   ptrdiff_t handle_count_;
5491 };
5492 
5493 
CheckHandleCount()5494 void Heap::CheckHandleCount() {
5495   CheckHandleCountVisitor v;
5496   isolate_->handle_scope_implementer()->Iterate(&v);
5497 }
5498 
5499 
next()5500 Space* AllSpaces::next() {
5501   switch (counter_++) {
5502     case NEW_SPACE:
5503       return heap_->new_space();
5504     case OLD_SPACE:
5505       return heap_->old_space();
5506     case CODE_SPACE:
5507       return heap_->code_space();
5508     case MAP_SPACE:
5509       return heap_->map_space();
5510     case LO_SPACE:
5511       return heap_->lo_space();
5512     default:
5513       return NULL;
5514   }
5515 }
5516 
5517 
next()5518 PagedSpace* PagedSpaces::next() {
5519   switch (counter_++) {
5520     case OLD_SPACE:
5521       return heap_->old_space();
5522     case CODE_SPACE:
5523       return heap_->code_space();
5524     case MAP_SPACE:
5525       return heap_->map_space();
5526     default:
5527       return NULL;
5528   }
5529 }
5530 
5531 
next()5532 OldSpace* OldSpaces::next() {
5533   switch (counter_++) {
5534     case OLD_SPACE:
5535       return heap_->old_space();
5536     case CODE_SPACE:
5537       return heap_->code_space();
5538     default:
5539       return NULL;
5540   }
5541 }
5542 
5543 
SpaceIterator(Heap * heap)5544 SpaceIterator::SpaceIterator(Heap* heap)
5545     : heap_(heap), current_space_(FIRST_SPACE), iterator_(NULL) {}
5546 
5547 
~SpaceIterator()5548 SpaceIterator::~SpaceIterator() {
5549   // Delete active iterator if any.
5550   delete iterator_;
5551 }
5552 
5553 
has_next()5554 bool SpaceIterator::has_next() {
5555   // Iterate until no more spaces.
5556   return current_space_ != LAST_SPACE;
5557 }
5558 
5559 
next()5560 ObjectIterator* SpaceIterator::next() {
5561   if (iterator_ != NULL) {
5562     delete iterator_;
5563     iterator_ = NULL;
5564     // Move to the next space
5565     current_space_++;
5566     if (current_space_ > LAST_SPACE) {
5567       return NULL;
5568     }
5569   }
5570 
5571   // Return iterator for the new current space.
5572   return CreateIterator();
5573 }
5574 
5575 
5576 // Create an iterator for the space to iterate.
CreateIterator()5577 ObjectIterator* SpaceIterator::CreateIterator() {
5578   DCHECK(iterator_ == NULL);
5579 
5580   switch (current_space_) {
5581     case NEW_SPACE:
5582       iterator_ = new SemiSpaceIterator(heap_->new_space());
5583       break;
5584     case OLD_SPACE:
5585       iterator_ = new HeapObjectIterator(heap_->old_space());
5586       break;
5587     case CODE_SPACE:
5588       iterator_ = new HeapObjectIterator(heap_->code_space());
5589       break;
5590     case MAP_SPACE:
5591       iterator_ = new HeapObjectIterator(heap_->map_space());
5592       break;
5593     case LO_SPACE:
5594       iterator_ = new LargeObjectIterator(heap_->lo_space());
5595       break;
5596   }
5597 
5598   // Return the newly allocated iterator;
5599   DCHECK(iterator_ != NULL);
5600   return iterator_;
5601 }
5602 
5603 
5604 class HeapObjectsFilter {
5605  public:
~HeapObjectsFilter()5606   virtual ~HeapObjectsFilter() {}
5607   virtual bool SkipObject(HeapObject* object) = 0;
5608 };
5609 
5610 
5611 class UnreachableObjectsFilter : public HeapObjectsFilter {
5612  public:
UnreachableObjectsFilter(Heap * heap)5613   explicit UnreachableObjectsFilter(Heap* heap) : heap_(heap) {
5614     MarkReachableObjects();
5615   }
5616 
~UnreachableObjectsFilter()5617   ~UnreachableObjectsFilter() {
5618     heap_->mark_compact_collector()->ClearMarkbits();
5619   }
5620 
SkipObject(HeapObject * object)5621   bool SkipObject(HeapObject* object) {
5622     if (object->IsFiller()) return true;
5623     MarkBit mark_bit = Marking::MarkBitFrom(object);
5624     return Marking::IsWhite(mark_bit);
5625   }
5626 
5627  private:
5628   class MarkingVisitor : public ObjectVisitor {
5629    public:
MarkingVisitor()5630     MarkingVisitor() : marking_stack_(10) {}
5631 
VisitPointers(Object ** start,Object ** end)5632     void VisitPointers(Object** start, Object** end) override {
5633       for (Object** p = start; p < end; p++) {
5634         if (!(*p)->IsHeapObject()) continue;
5635         HeapObject* obj = HeapObject::cast(*p);
5636         MarkBit mark_bit = Marking::MarkBitFrom(obj);
5637         if (Marking::IsWhite(mark_bit)) {
5638           Marking::WhiteToBlack(mark_bit);
5639           marking_stack_.Add(obj);
5640         }
5641       }
5642     }
5643 
TransitiveClosure()5644     void TransitiveClosure() {
5645       while (!marking_stack_.is_empty()) {
5646         HeapObject* obj = marking_stack_.RemoveLast();
5647         obj->Iterate(this);
5648       }
5649     }
5650 
5651    private:
5652     List<HeapObject*> marking_stack_;
5653   };
5654 
MarkReachableObjects()5655   void MarkReachableObjects() {
5656     MarkingVisitor visitor;
5657     heap_->IterateRoots(&visitor, VISIT_ALL);
5658     visitor.TransitiveClosure();
5659   }
5660 
5661   Heap* heap_;
5662   DisallowHeapAllocation no_allocation_;
5663 };
5664 
5665 
HeapIterator(Heap * heap,HeapIterator::HeapObjectsFiltering filtering)5666 HeapIterator::HeapIterator(Heap* heap,
5667                            HeapIterator::HeapObjectsFiltering filtering)
5668     : make_heap_iterable_helper_(heap),
5669       no_heap_allocation_(),
5670       heap_(heap),
5671       filtering_(filtering),
5672       filter_(nullptr),
5673       space_iterator_(nullptr),
5674       object_iterator_(nullptr) {
5675   heap_->heap_iterator_start();
5676   // Start the iteration.
5677   space_iterator_ = new SpaceIterator(heap_);
5678   switch (filtering_) {
5679     case kFilterUnreachable:
5680       filter_ = new UnreachableObjectsFilter(heap_);
5681       break;
5682     default:
5683       break;
5684   }
5685   object_iterator_ = space_iterator_->next();
5686 }
5687 
5688 
~HeapIterator()5689 HeapIterator::~HeapIterator() {
5690   heap_->heap_iterator_end();
5691 #ifdef DEBUG
5692   // Assert that in filtering mode we have iterated through all
5693   // objects. Otherwise, heap will be left in an inconsistent state.
5694   if (filtering_ != kNoFiltering) {
5695     DCHECK(object_iterator_ == nullptr);
5696   }
5697 #endif
5698   // Make sure the last iterator is deallocated.
5699   delete object_iterator_;
5700   delete space_iterator_;
5701   delete filter_;
5702 }
5703 
5704 
next()5705 HeapObject* HeapIterator::next() {
5706   if (filter_ == nullptr) return NextObject();
5707 
5708   HeapObject* obj = NextObject();
5709   while ((obj != nullptr) && (filter_->SkipObject(obj))) obj = NextObject();
5710   return obj;
5711 }
5712 
5713 
NextObject()5714 HeapObject* HeapIterator::NextObject() {
5715   // No iterator means we are done.
5716   if (object_iterator_ == nullptr) return nullptr;
5717 
5718   if (HeapObject* obj = object_iterator_->next_object()) {
5719     // If the current iterator has more objects we are fine.
5720     return obj;
5721   } else {
5722     // Go though the spaces looking for one that has objects.
5723     while (space_iterator_->has_next()) {
5724       object_iterator_ = space_iterator_->next();
5725       if (HeapObject* obj = object_iterator_->next_object()) {
5726         return obj;
5727       }
5728     }
5729   }
5730   // Done with the last space.
5731   object_iterator_ = nullptr;
5732   return nullptr;
5733 }
5734 
5735 
5736 #ifdef DEBUG
5737 
5738 Object* const PathTracer::kAnyGlobalObject = NULL;
5739 
5740 class PathTracer::MarkVisitor : public ObjectVisitor {
5741  public:
MarkVisitor(PathTracer * tracer)5742   explicit MarkVisitor(PathTracer* tracer) : tracer_(tracer) {}
5743 
VisitPointers(Object ** start,Object ** end)5744   void VisitPointers(Object** start, Object** end) override {
5745     // Scan all HeapObject pointers in [start, end)
5746     for (Object** p = start; !tracer_->found() && (p < end); p++) {
5747       if ((*p)->IsHeapObject()) tracer_->MarkRecursively(p, this);
5748     }
5749   }
5750 
5751  private:
5752   PathTracer* tracer_;
5753 };
5754 
5755 
5756 class PathTracer::UnmarkVisitor : public ObjectVisitor {
5757  public:
UnmarkVisitor(PathTracer * tracer)5758   explicit UnmarkVisitor(PathTracer* tracer) : tracer_(tracer) {}
5759 
VisitPointers(Object ** start,Object ** end)5760   void VisitPointers(Object** start, Object** end) override {
5761     // Scan all HeapObject pointers in [start, end)
5762     for (Object** p = start; p < end; p++) {
5763       if ((*p)->IsHeapObject()) tracer_->UnmarkRecursively(p, this);
5764     }
5765   }
5766 
5767  private:
5768   PathTracer* tracer_;
5769 };
5770 
5771 
VisitPointers(Object ** start,Object ** end)5772 void PathTracer::VisitPointers(Object** start, Object** end) {
5773   bool done = ((what_to_find_ == FIND_FIRST) && found_target_);
5774   // Visit all HeapObject pointers in [start, end)
5775   for (Object** p = start; !done && (p < end); p++) {
5776     if ((*p)->IsHeapObject()) {
5777       TracePathFrom(p);
5778       done = ((what_to_find_ == FIND_FIRST) && found_target_);
5779     }
5780   }
5781 }
5782 
5783 
Reset()5784 void PathTracer::Reset() {
5785   found_target_ = false;
5786   object_stack_.Clear();
5787 }
5788 
5789 
TracePathFrom(Object ** root)5790 void PathTracer::TracePathFrom(Object** root) {
5791   DCHECK((search_target_ == kAnyGlobalObject) ||
5792          search_target_->IsHeapObject());
5793   found_target_in_trace_ = false;
5794   Reset();
5795 
5796   MarkVisitor mark_visitor(this);
5797   MarkRecursively(root, &mark_visitor);
5798 
5799   UnmarkVisitor unmark_visitor(this);
5800   UnmarkRecursively(root, &unmark_visitor);
5801 
5802   ProcessResults();
5803 }
5804 
5805 
SafeIsNativeContext(HeapObject * obj)5806 static bool SafeIsNativeContext(HeapObject* obj) {
5807   return obj->map() == obj->GetHeap()->root(Heap::kNativeContextMapRootIndex);
5808 }
5809 
5810 
MarkRecursively(Object ** p,MarkVisitor * mark_visitor)5811 void PathTracer::MarkRecursively(Object** p, MarkVisitor* mark_visitor) {
5812   if (!(*p)->IsHeapObject()) return;
5813 
5814   HeapObject* obj = HeapObject::cast(*p);
5815 
5816   MapWord map_word = obj->map_word();
5817   if (!map_word.ToMap()->IsHeapObject()) return;  // visited before
5818 
5819   if (found_target_in_trace_) return;  // stop if target found
5820   object_stack_.Add(obj);
5821   if (((search_target_ == kAnyGlobalObject) && obj->IsJSGlobalObject()) ||
5822       (obj == search_target_)) {
5823     found_target_in_trace_ = true;
5824     found_target_ = true;
5825     return;
5826   }
5827 
5828   bool is_native_context = SafeIsNativeContext(obj);
5829 
5830   // not visited yet
5831   Map* map = Map::cast(map_word.ToMap());
5832 
5833   MapWord marked_map_word =
5834       MapWord::FromRawValue(obj->map_word().ToRawValue() + kMarkTag);
5835   obj->set_map_word(marked_map_word);
5836 
5837   // Scan the object body.
5838   if (is_native_context && (visit_mode_ == VISIT_ONLY_STRONG)) {
5839     // This is specialized to scan Context's properly.
5840     Object** start =
5841         reinterpret_cast<Object**>(obj->address() + Context::kHeaderSize);
5842     Object** end =
5843         reinterpret_cast<Object**>(obj->address() + Context::kHeaderSize +
5844                                    Context::FIRST_WEAK_SLOT * kPointerSize);
5845     mark_visitor->VisitPointers(start, end);
5846   } else {
5847     obj->IterateBody(map->instance_type(), obj->SizeFromMap(map), mark_visitor);
5848   }
5849 
5850   // Scan the map after the body because the body is a lot more interesting
5851   // when doing leak detection.
5852   MarkRecursively(reinterpret_cast<Object**>(&map), mark_visitor);
5853 
5854   if (!found_target_in_trace_) {  // don't pop if found the target
5855     object_stack_.RemoveLast();
5856   }
5857 }
5858 
5859 
UnmarkRecursively(Object ** p,UnmarkVisitor * unmark_visitor)5860 void PathTracer::UnmarkRecursively(Object** p, UnmarkVisitor* unmark_visitor) {
5861   if (!(*p)->IsHeapObject()) return;
5862 
5863   HeapObject* obj = HeapObject::cast(*p);
5864 
5865   MapWord map_word = obj->map_word();
5866   if (map_word.ToMap()->IsHeapObject()) return;  // unmarked already
5867 
5868   MapWord unmarked_map_word =
5869       MapWord::FromRawValue(map_word.ToRawValue() - kMarkTag);
5870   obj->set_map_word(unmarked_map_word);
5871 
5872   Map* map = Map::cast(unmarked_map_word.ToMap());
5873 
5874   UnmarkRecursively(reinterpret_cast<Object**>(&map), unmark_visitor);
5875 
5876   obj->IterateBody(map->instance_type(), obj->SizeFromMap(map), unmark_visitor);
5877 }
5878 
5879 
ProcessResults()5880 void PathTracer::ProcessResults() {
5881   if (found_target_) {
5882     OFStream os(stdout);
5883     os << "=====================================\n"
5884        << "====        Path to object       ====\n"
5885        << "=====================================\n\n";
5886 
5887     DCHECK(!object_stack_.is_empty());
5888     for (int i = 0; i < object_stack_.length(); i++) {
5889       if (i > 0) os << "\n     |\n     |\n     V\n\n";
5890       object_stack_[i]->Print(os);
5891     }
5892     os << "=====================================\n";
5893   }
5894 }
5895 
5896 
5897 // Triggers a depth-first traversal of reachable objects from one
5898 // given root object and finds a path to a specific heap object and
5899 // prints it.
TracePathToObjectFrom(Object * target,Object * root)5900 void Heap::TracePathToObjectFrom(Object* target, Object* root) {
5901   PathTracer tracer(target, PathTracer::FIND_ALL, VISIT_ALL);
5902   tracer.VisitPointer(&root);
5903 }
5904 
5905 
5906 // Triggers a depth-first traversal of reachable objects from roots
5907 // and finds a path to a specific heap object and prints it.
TracePathToObject(Object * target)5908 void Heap::TracePathToObject(Object* target) {
5909   PathTracer tracer(target, PathTracer::FIND_ALL, VISIT_ALL);
5910   IterateRoots(&tracer, VISIT_ONLY_STRONG);
5911 }
5912 
5913 
5914 // Triggers a depth-first traversal of reachable objects from roots
5915 // and finds a path to any global object and prints it. Useful for
5916 // determining the source for leaks of global objects.
TracePathToGlobal()5917 void Heap::TracePathToGlobal() {
5918   PathTracer tracer(PathTracer::kAnyGlobalObject, PathTracer::FIND_ALL,
5919                     VISIT_ALL);
5920   IterateRoots(&tracer, VISIT_ONLY_STRONG);
5921 }
5922 #endif
5923 
5924 
UpdateCumulativeGCStatistics(double duration,double spent_in_mutator,double marking_time)5925 void Heap::UpdateCumulativeGCStatistics(double duration,
5926                                         double spent_in_mutator,
5927                                         double marking_time) {
5928   if (FLAG_print_cumulative_gc_stat) {
5929     total_gc_time_ms_ += duration;
5930     max_gc_pause_ = Max(max_gc_pause_, duration);
5931     max_alive_after_gc_ = Max(max_alive_after_gc_, SizeOfObjects());
5932     min_in_mutator_ = Min(min_in_mutator_, spent_in_mutator);
5933   } else if (FLAG_trace_gc_verbose) {
5934     total_gc_time_ms_ += duration;
5935   }
5936 
5937   marking_time_ += marking_time;
5938 }
5939 
5940 
Hash(Handle<Map> map,Handle<Name> name)5941 int KeyedLookupCache::Hash(Handle<Map> map, Handle<Name> name) {
5942   DisallowHeapAllocation no_gc;
5943   // Uses only lower 32 bits if pointers are larger.
5944   uintptr_t addr_hash =
5945       static_cast<uint32_t>(reinterpret_cast<uintptr_t>(*map)) >> kMapHashShift;
5946   return static_cast<uint32_t>((addr_hash ^ name->Hash()) & kCapacityMask);
5947 }
5948 
5949 
Lookup(Handle<Map> map,Handle<Name> name)5950 int KeyedLookupCache::Lookup(Handle<Map> map, Handle<Name> name) {
5951   DisallowHeapAllocation no_gc;
5952   int index = (Hash(map, name) & kHashMask);
5953   for (int i = 0; i < kEntriesPerBucket; i++) {
5954     Key& key = keys_[index + i];
5955     if ((key.map == *map) && key.name->Equals(*name)) {
5956       return field_offsets_[index + i];
5957     }
5958   }
5959   return kNotFound;
5960 }
5961 
5962 
Update(Handle<Map> map,Handle<Name> name,int field_offset)5963 void KeyedLookupCache::Update(Handle<Map> map, Handle<Name> name,
5964                               int field_offset) {
5965   DisallowHeapAllocation no_gc;
5966   if (!name->IsUniqueName()) {
5967     if (!StringTable::InternalizeStringIfExists(
5968              name->GetIsolate(), Handle<String>::cast(name)).ToHandle(&name)) {
5969       return;
5970     }
5971   }
5972   // This cache is cleared only between mark compact passes, so we expect the
5973   // cache to only contain old space names.
5974   DCHECK(!map->GetIsolate()->heap()->InNewSpace(*name));
5975 
5976   int index = (Hash(map, name) & kHashMask);
5977   // After a GC there will be free slots, so we use them in order (this may
5978   // help to get the most frequently used one in position 0).
5979   for (int i = 0; i < kEntriesPerBucket; i++) {
5980     Key& key = keys_[index];
5981     Object* free_entry_indicator = NULL;
5982     if (key.map == free_entry_indicator) {
5983       key.map = *map;
5984       key.name = *name;
5985       field_offsets_[index + i] = field_offset;
5986       return;
5987     }
5988   }
5989   // No free entry found in this bucket, so we move them all down one and
5990   // put the new entry at position zero.
5991   for (int i = kEntriesPerBucket - 1; i > 0; i--) {
5992     Key& key = keys_[index + i];
5993     Key& key2 = keys_[index + i - 1];
5994     key = key2;
5995     field_offsets_[index + i] = field_offsets_[index + i - 1];
5996   }
5997 
5998   // Write the new first entry.
5999   Key& key = keys_[index];
6000   key.map = *map;
6001   key.name = *name;
6002   field_offsets_[index] = field_offset;
6003 }
6004 
6005 
Clear()6006 void KeyedLookupCache::Clear() {
6007   for (int index = 0; index < kLength; index++) keys_[index].map = NULL;
6008 }
6009 
6010 
Clear()6011 void DescriptorLookupCache::Clear() {
6012   for (int index = 0; index < kLength; index++) keys_[index].source = NULL;
6013 }
6014 
6015 
CleanUp()6016 void Heap::ExternalStringTable::CleanUp() {
6017   int last = 0;
6018   for (int i = 0; i < new_space_strings_.length(); ++i) {
6019     if (new_space_strings_[i] == heap_->the_hole_value()) {
6020       continue;
6021     }
6022     DCHECK(new_space_strings_[i]->IsExternalString());
6023     if (heap_->InNewSpace(new_space_strings_[i])) {
6024       new_space_strings_[last++] = new_space_strings_[i];
6025     } else {
6026       old_space_strings_.Add(new_space_strings_[i]);
6027     }
6028   }
6029   new_space_strings_.Rewind(last);
6030   new_space_strings_.Trim();
6031 
6032   last = 0;
6033   for (int i = 0; i < old_space_strings_.length(); ++i) {
6034     if (old_space_strings_[i] == heap_->the_hole_value()) {
6035       continue;
6036     }
6037     DCHECK(old_space_strings_[i]->IsExternalString());
6038     DCHECK(!heap_->InNewSpace(old_space_strings_[i]));
6039     old_space_strings_[last++] = old_space_strings_[i];
6040   }
6041   old_space_strings_.Rewind(last);
6042   old_space_strings_.Trim();
6043 #ifdef VERIFY_HEAP
6044   if (FLAG_verify_heap) {
6045     Verify();
6046   }
6047 #endif
6048 }
6049 
6050 
TearDown()6051 void Heap::ExternalStringTable::TearDown() {
6052   for (int i = 0; i < new_space_strings_.length(); ++i) {
6053     heap_->FinalizeExternalString(ExternalString::cast(new_space_strings_[i]));
6054   }
6055   new_space_strings_.Free();
6056   for (int i = 0; i < old_space_strings_.length(); ++i) {
6057     heap_->FinalizeExternalString(ExternalString::cast(old_space_strings_[i]));
6058   }
6059   old_space_strings_.Free();
6060 }
6061 
6062 
6063 class Heap::UnmapFreeMemoryTask : public v8::Task {
6064  public:
UnmapFreeMemoryTask(Heap * heap,MemoryChunk * head)6065   UnmapFreeMemoryTask(Heap* heap, MemoryChunk* head)
6066       : heap_(heap), head_(head) {}
~UnmapFreeMemoryTask()6067   virtual ~UnmapFreeMemoryTask() {}
6068 
6069  private:
6070   // v8::Task overrides.
Run()6071   void Run() override {
6072     heap_->FreeQueuedChunks(head_);
6073     heap_->pending_unmapping_tasks_semaphore_.Signal();
6074   }
6075 
6076   Heap* heap_;
6077   MemoryChunk* head_;
6078 
6079   DISALLOW_COPY_AND_ASSIGN(UnmapFreeMemoryTask);
6080 };
6081 
6082 
WaitUntilUnmappingOfFreeChunksCompleted()6083 void Heap::WaitUntilUnmappingOfFreeChunksCompleted() {
6084   while (concurrent_unmapping_tasks_active_ > 0) {
6085     pending_unmapping_tasks_semaphore_.Wait();
6086     concurrent_unmapping_tasks_active_--;
6087   }
6088 }
6089 
6090 
QueueMemoryChunkForFree(MemoryChunk * chunk)6091 void Heap::QueueMemoryChunkForFree(MemoryChunk* chunk) {
6092   // PreFree logically frees the memory chunk. However, the actual freeing
6093   // will happen on a separate thread sometime later.
6094   isolate_->memory_allocator()->PreFreeMemory(chunk);
6095 
6096   // The chunks added to this queue will be freed by a concurrent thread.
6097   chunk->set_next_chunk(chunks_queued_for_free_);
6098   chunks_queued_for_free_ = chunk;
6099 }
6100 
6101 
FilterStoreBufferEntriesOnAboutToBeFreedPages()6102 void Heap::FilterStoreBufferEntriesOnAboutToBeFreedPages() {
6103   if (chunks_queued_for_free_ == NULL) return;
6104   MemoryChunk* next;
6105   MemoryChunk* chunk;
6106   for (chunk = chunks_queued_for_free_; chunk != NULL; chunk = next) {
6107     next = chunk->next_chunk();
6108     chunk->SetFlag(MemoryChunk::ABOUT_TO_BE_FREED);
6109   }
6110   store_buffer()->Compact();
6111   store_buffer()->Filter(MemoryChunk::ABOUT_TO_BE_FREED);
6112 }
6113 
6114 
FreeQueuedChunks()6115 void Heap::FreeQueuedChunks() {
6116   if (chunks_queued_for_free_ != NULL) {
6117     if (FLAG_concurrent_sweeping) {
6118       V8::GetCurrentPlatform()->CallOnBackgroundThread(
6119           new UnmapFreeMemoryTask(this, chunks_queued_for_free_),
6120           v8::Platform::kShortRunningTask);
6121     } else {
6122       FreeQueuedChunks(chunks_queued_for_free_);
6123       pending_unmapping_tasks_semaphore_.Signal();
6124     }
6125     chunks_queued_for_free_ = NULL;
6126   } else {
6127     // If we do not have anything to unmap, we just signal the semaphore
6128     // that we are done.
6129     pending_unmapping_tasks_semaphore_.Signal();
6130   }
6131   concurrent_unmapping_tasks_active_++;
6132 }
6133 
6134 
FreeQueuedChunks(MemoryChunk * list_head)6135 void Heap::FreeQueuedChunks(MemoryChunk* list_head) {
6136   MemoryChunk* next;
6137   MemoryChunk* chunk;
6138   for (chunk = list_head; chunk != NULL; chunk = next) {
6139     next = chunk->next_chunk();
6140     isolate_->memory_allocator()->PerformFreeMemory(chunk);
6141   }
6142 }
6143 
6144 
RememberUnmappedPage(Address page,bool compacted)6145 void Heap::RememberUnmappedPage(Address page, bool compacted) {
6146   uintptr_t p = reinterpret_cast<uintptr_t>(page);
6147   // Tag the page pointer to make it findable in the dump file.
6148   if (compacted) {
6149     p ^= 0xc1ead & (Page::kPageSize - 1);  // Cleared.
6150   } else {
6151     p ^= 0x1d1ed & (Page::kPageSize - 1);  // I died.
6152   }
6153   remembered_unmapped_pages_[remembered_unmapped_pages_index_] =
6154       reinterpret_cast<Address>(p);
6155   remembered_unmapped_pages_index_++;
6156   remembered_unmapped_pages_index_ %= kRememberedUnmappedPages;
6157 }
6158 
6159 
RegisterStrongRoots(Object ** start,Object ** end)6160 void Heap::RegisterStrongRoots(Object** start, Object** end) {
6161   StrongRootsList* list = new StrongRootsList();
6162   list->next = strong_roots_list_;
6163   list->start = start;
6164   list->end = end;
6165   strong_roots_list_ = list;
6166 }
6167 
6168 
UnregisterStrongRoots(Object ** start)6169 void Heap::UnregisterStrongRoots(Object** start) {
6170   StrongRootsList* prev = NULL;
6171   StrongRootsList* list = strong_roots_list_;
6172   while (list != nullptr) {
6173     StrongRootsList* next = list->next;
6174     if (list->start == start) {
6175       if (prev) {
6176         prev->next = next;
6177       } else {
6178         strong_roots_list_ = next;
6179       }
6180       delete list;
6181     } else {
6182       prev = list;
6183     }
6184     list = next;
6185   }
6186 }
6187 
6188 
NumberOfTrackedHeapObjectTypes()6189 size_t Heap::NumberOfTrackedHeapObjectTypes() {
6190   return ObjectStats::OBJECT_STATS_COUNT;
6191 }
6192 
6193 
ObjectCountAtLastGC(size_t index)6194 size_t Heap::ObjectCountAtLastGC(size_t index) {
6195   if (index >= ObjectStats::OBJECT_STATS_COUNT) return 0;
6196   return object_stats_->object_count_last_gc(index);
6197 }
6198 
6199 
ObjectSizeAtLastGC(size_t index)6200 size_t Heap::ObjectSizeAtLastGC(size_t index) {
6201   if (index >= ObjectStats::OBJECT_STATS_COUNT) return 0;
6202   return object_stats_->object_size_last_gc(index);
6203 }
6204 
6205 
GetObjectTypeName(size_t index,const char ** object_type,const char ** object_sub_type)6206 bool Heap::GetObjectTypeName(size_t index, const char** object_type,
6207                              const char** object_sub_type) {
6208   if (index >= ObjectStats::OBJECT_STATS_COUNT) return false;
6209 
6210   switch (static_cast<int>(index)) {
6211 #define COMPARE_AND_RETURN_NAME(name) \
6212   case name:                          \
6213     *object_type = #name;             \
6214     *object_sub_type = "";            \
6215     return true;
6216     INSTANCE_TYPE_LIST(COMPARE_AND_RETURN_NAME)
6217 #undef COMPARE_AND_RETURN_NAME
6218 #define COMPARE_AND_RETURN_NAME(name)                      \
6219   case ObjectStats::FIRST_CODE_KIND_SUB_TYPE + Code::name: \
6220     *object_type = "CODE_TYPE";                            \
6221     *object_sub_type = "CODE_KIND/" #name;                 \
6222     return true;
6223     CODE_KIND_LIST(COMPARE_AND_RETURN_NAME)
6224 #undef COMPARE_AND_RETURN_NAME
6225 #define COMPARE_AND_RETURN_NAME(name)                  \
6226   case ObjectStats::FIRST_FIXED_ARRAY_SUB_TYPE + name: \
6227     *object_type = "FIXED_ARRAY_TYPE";                 \
6228     *object_sub_type = #name;                          \
6229     return true;
6230     FIXED_ARRAY_SUB_INSTANCE_TYPE_LIST(COMPARE_AND_RETURN_NAME)
6231 #undef COMPARE_AND_RETURN_NAME
6232 #define COMPARE_AND_RETURN_NAME(name)                                  \
6233   case ObjectStats::FIRST_CODE_AGE_SUB_TYPE + Code::k##name##CodeAge - \
6234       Code::kFirstCodeAge:                                             \
6235     *object_type = "CODE_TYPE";                                        \
6236     *object_sub_type = "CODE_AGE/" #name;                              \
6237     return true;
6238     CODE_AGE_LIST_COMPLETE(COMPARE_AND_RETURN_NAME)
6239 #undef COMPARE_AND_RETURN_NAME
6240   }
6241   return false;
6242 }
6243 
6244 
6245 // static
GetStaticVisitorIdForMap(Map * map)6246 int Heap::GetStaticVisitorIdForMap(Map* map) {
6247   return StaticVisitorBase::GetVisitorId(map);
6248 }
6249 
6250 }  // namespace internal
6251 }  // namespace v8
6252