src/mark_sweep.cc - platform/art - Gitiles

 /*
  * Copyright (C) 2011 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "mark_sweep.h"

 #include <climits>
 #include <vector>

 #include "class_loader.h"
 #include "dex_cache.h"
 #include "heap.h"
 #include "indirect_reference_table.h"
 #include "intern_table.h"
 #include "logging.h"
 #include "macros.h"
 #include "mark_stack.h"
 #include "monitor.h"
 #include "object.h"
 #include "runtime.h"
 #include "space.h"
 #include "timing_logger.h"
 #include "thread.h"

 namespace art {

 void MarkSweep::Init() {
   mark_stack_ = MarkStack::Create();

   heap_ = Runtime::Current()->GetHeap();
   mark_bitmap_ = heap_->GetMarkBits();
   live_bitmap_ = heap_->GetLiveBits();

   // TODO: if concurrent, clear the card table.

   // TODO: if concurrent, enable card marking in compiler

   // TODO: check that the mark bitmap is entirely clear.
 }

 inline void MarkSweep::MarkObject0(const Object* obj, bool check_finger) {
   DCHECK(obj != NULL);
   if (obj < condemned_) {
     DCHECK(IsMarked(obj));
     return;
   }
   bool is_marked = mark_bitmap_->Test(obj);
   // This object was not previously marked.
   if (!is_marked) {
     mark_bitmap_->Set(obj);
     if (check_finger && obj < finger_) {
       // The object must be pushed on to the mark stack.
       mark_stack_->Push(obj);
     }
   }
 }

 // Used to mark objects when recursing.  Recursion is done by moving
 // the finger across the bitmaps in address order and marking child
 // objects.  Any newly-marked objects whose addresses are lower than
 // the finger won't be visited by the bitmap scan, so those objects
 // need to be added to the mark stack.
 inline void MarkSweep::MarkObject(const Object* obj) {
   if (obj != NULL) {
     MarkObject0(obj, true);
   }
 }

 void MarkSweep::MarkObjectVisitor(const Object* root, void* arg) {
   DCHECK(root != NULL);
   DCHECK(arg != NULL);
   MarkSweep* mark_sweep = reinterpret_cast<MarkSweep*>(arg);
   DCHECK(mark_sweep->finger_ == NULL);  // no point to check finger if it is NULL
   mark_sweep->MarkObject0(root, false);
 }

 // Marks all objects in the root set.
 void MarkSweep::MarkRoots() {
   Runtime::Current()->VisitRoots(MarkObjectVisitor, this);
 }

 void MarkSweep::ScanImageRootVisitor(Object* root, void* arg) {
   DCHECK(root != NULL);
   DCHECK(arg != NULL);
   MarkSweep* mark_sweep = reinterpret_cast<MarkSweep*>(arg);
   DCHECK(mark_sweep->finger_ == NULL);  // no point to check finger if it is NULL
   mark_sweep->MarkObject0(root, false);
   mark_sweep->ScanObject(root);
 }

 // Marks all objects that are in images and have been touched by the mutator
 void MarkSweep::ScanDirtyImageRoots() {
   const std::vector<Space*>& spaces = heap_->GetSpaces();
   CardTable* card_table = heap_->GetCardTable();
   for (size_t i = 0; i < spaces.size(); ++i) {
     if (spaces[i]->IsImageSpace()) {
       byte* begin = spaces[i]->Begin();
       byte* end = spaces[i]->End();
       card_table->Scan(begin, end, ScanImageRootVisitor, this);
     }
   }
 }

 void MarkSweep::CheckBitmapCallback(Object* obj, void* finger, void* arg) {
   MarkSweep* mark_sweep = reinterpret_cast<MarkSweep*>(arg);
   mark_sweep->finger_ = reinterpret_cast<Object*>(finger);
   mark_sweep->CheckObject(obj);
 }

 void MarkSweep::ScanBitmapCallback(Object* obj, void* finger, void* arg) {
   MarkSweep* mark_sweep = reinterpret_cast<MarkSweep*>(arg);
   mark_sweep->finger_ = reinterpret_cast<Object*>(finger);
   mark_sweep->ScanObject(obj);
 }

 // Populates the mark stack based on the set of marked objects and
 // recursively marks until the mark stack is emptied.
 void MarkSweep::RecursiveMark() {
   // RecursiveMark will build the lists of known instances of the Reference classes.
   // See DelayReferenceReferent for details.
   CHECK(soft_reference_list_ == NULL);
   CHECK(weak_reference_list_ == NULL);
   CHECK(finalizer_reference_list_ == NULL);
   CHECK(phantom_reference_list_ == NULL);
   CHECK(cleared_reference_list_ == NULL);

   void* arg = reinterpret_cast<void*>(this);
   const std::vector<Space*>& spaces = heap_->GetSpaces();
   for (size_t i = 0; i < spaces.size(); ++i) {
 #ifndef NDEBUG
     uintptr_t begin = reinterpret_cast<uintptr_t>(spaces[i]->Begin());
     uintptr_t end = reinterpret_cast<uintptr_t>(spaces[i]->End());
     if (!spaces[i]->IsImageSpace()) {
       mark_bitmap_->ScanWalk(begin, end, &MarkSweep::ScanBitmapCallback, arg);
     } else {
       mark_bitmap_->ScanWalk(begin, end, &MarkSweep::CheckBitmapCallback, arg);
     }
 #else
     if (!spaces[i]->IsImageSpace()) {
       uintptr_t begin = reinterpret_cast<uintptr_t>(spaces[i]->Begin());
       uintptr_t end = reinterpret_cast<uintptr_t>(spaces[i]->End());
       mark_bitmap_->ScanWalk(begin, end, &MarkSweep::ScanBitmapCallback, arg);
     }
 #endif
   }
   finger_ = reinterpret_cast<Object*>(~0);
   // TODO: tune the frequency of emptying the mark stack
   ProcessMarkStack();
 }

 void MarkSweep::ReMarkRoots() {
   UNIMPLEMENTED(FATAL);
 }

 void MarkSweep::SweepJniWeakGlobals() {
   JavaVMExt* vm = Runtime::Current()->GetJavaVM();
   MutexLock mu(vm->weak_globals_lock);
   IndirectReferenceTable* table = &vm->weak_globals;
   typedef IndirectReferenceTable::iterator It; // TODO: C++0x auto
   for (It it = table->begin(), end = table->end(); it != end; ++it) {
     const Object** entry = *it;
     if (!IsMarked(*entry)) {
       *entry = kClearedJniWeakGlobal;
     }
   }
 }

 void MarkSweep::SweepSystemWeaks() {
   Runtime::Current()->GetInternTable()->SweepInternTableWeaks(IsMarked, this);
   Runtime::Current()->GetMonitorList()->SweepMonitorList(IsMarked, this);
   SweepJniWeakGlobals();
 }

 struct SweepCallbackContext {
   Heap* heap;
   AllocSpace* space;
 };

 void MarkSweep::SweepCallback(size_t num_ptrs, Object** ptrs, void* arg) {
   // TODO: lock heap if concurrent
   size_t freed_objects = num_ptrs;
   size_t freed_bytes = 0;
   SweepCallbackContext* context = static_cast<SweepCallbackContext*>(arg);
   Heap* heap = context->heap;
   AllocSpace* space = context->space;
   // Use a bulk free, that merges consecutive objects before freeing or free per object?
   // Documentation suggests better free performance with merging, but this may be at the expensive
   // of allocation.
   // TODO: investigate performance
   static const bool kUseFreeList = true;
   if (kUseFreeList) {
     for (size_t i = 0; i < num_ptrs; ++i) {
       Object* obj = static_cast<Object*>(ptrs[i]);
       freed_bytes += space->AllocationSize(obj);
       heap->GetLiveBits()->Clear(obj);
     }
     // AllocSpace::FreeList clears the value in ptrs, so perform after clearing the live bit
     space->FreeList(num_ptrs, ptrs);
   } else {
     for (size_t i = 0; i < num_ptrs; ++i) {
       Object* obj = static_cast<Object*>(ptrs[i]);
       freed_bytes += space->AllocationSize(obj);
       heap->GetLiveBits()->Clear(obj);
       space->Free(obj);
     }
   }
   heap->RecordFreeLocked(freed_objects, freed_bytes);
   // TODO: unlock heap if concurrent
 }

 void MarkSweep::Sweep() {
   SweepSystemWeaks();

   const std::vector<Space*>& spaces = heap_->GetSpaces();
   SweepCallbackContext scc;
   scc.heap = heap_;
   for (size_t i = 0; i < spaces.size(); ++i) {
     if (!spaces[i]->IsImageSpace()) {
       uintptr_t begin = reinterpret_cast<uintptr_t>(spaces[i]->Begin());
       uintptr_t end = reinterpret_cast<uintptr_t>(spaces[i]->End());
       scc.space = spaces[i]->AsAllocSpace();
       HeapBitmap::SweepWalk(*live_bitmap_, *mark_bitmap_, begin, end,
                             &MarkSweep::SweepCallback, reinterpret_cast<void*>(&scc));
     }
   }
 }

 // Scans instance fields.
 inline void MarkSweep::ScanInstanceFields(const Object* obj) {
   DCHECK(obj != NULL);
   Class* klass = obj->GetClass();
   DCHECK(klass != NULL);
   ScanFields(obj, klass->GetReferenceInstanceOffsets(), false);
 }

 inline void MarkSweep::CheckInstanceFields(const Object* obj) {
   Class* klass = obj->GetClass();
   CheckFields(obj, klass->GetReferenceInstanceOffsets(), false);
 }

 // Scans static storage on a Class.
 inline void MarkSweep::ScanStaticFields(const Class* klass) {
   DCHECK(klass != NULL);
   ScanFields(klass, klass->GetReferenceStaticOffsets(), true);
 }

 inline void MarkSweep::CheckStaticFields(const Class* klass) {
   CheckFields(klass, klass->GetReferenceStaticOffsets(), true);
 }

 inline void MarkSweep::ScanFields(const Object* obj, uint32_t ref_offsets, bool is_static) {
   if (ref_offsets != CLASS_WALK_SUPER) {
     // Found a reference offset bitmap.  Mark the specified offsets.
     while (ref_offsets != 0) {
       size_t right_shift = CLZ(ref_offsets);
       MemberOffset byte_offset = CLASS_OFFSET_FROM_CLZ(right_shift);
       const Object* ref = obj->GetFieldObject<const Object*>(byte_offset, false);
       MarkObject(ref);
       ref_offsets &= ~(CLASS_HIGH_BIT >> right_shift);
     }
   } else {
     // There is no reference offset bitmap.  In the non-static case,
     // walk up the class inheritance hierarchy and find reference
     // offsets the hard way. In the static case, just consider this
     // class.
     for (const Class* klass = is_static ? obj->AsClass() : obj->GetClass();
          klass != NULL;
          klass = is_static ? NULL : klass->GetSuperClass()) {
       size_t num_reference_fields = (is_static
                                      ? klass->NumReferenceStaticFields()
                                      : klass->NumReferenceInstanceFields());
       for (size_t i = 0; i < num_reference_fields; ++i) {
         Field* field = (is_static
                         ? klass->GetStaticField(i)
                         : klass->GetInstanceField(i));
         MemberOffset field_offset = field->GetOffset();
         const Object* ref = obj->GetFieldObject<const Object*>(field_offset, false);
         MarkObject(ref);
       }
     }
   }
 }

 inline void MarkSweep::CheckReference(const Object* obj, const Object* ref, MemberOffset offset, bool is_static) {
   AllocSpace* alloc_space = heap_->GetAllocSpace();
   if (alloc_space->Contains(ref)) {
     bool is_marked = mark_bitmap_->Test(ref);
     if (!is_marked) {
       LOG(INFO) << *alloc_space;
       LOG(WARNING) << (is_static ? "Static ref'" : "Instance ref'") << PrettyTypeOf(ref)
                    << "' (" << reinterpret_cast<const void*>(ref) << ") in '" << PrettyTypeOf(obj)
                    << "' (" << reinterpret_cast<const void*>(obj) << ") at offset "
                    << reinterpret_cast<void*>(offset.Int32Value()) << " wasn't marked";
       bool obj_marked = heap_->GetCardTable()->IsDirty(obj);
       if (!obj_marked) {
         LOG(WARNING) << "Object '" << PrettyTypeOf(obj) << "' "
                      << "(" << reinterpret_cast<const void*>(obj) << ") contains references to "
                      << "the alloc space, but wasn't card marked";
       }
     }
   }
 }

 inline void MarkSweep::CheckFields(const Object* obj, uint32_t ref_offsets, bool is_static) {
   if (ref_offsets != CLASS_WALK_SUPER) {
     // Found a reference offset bitmap.  Mark the specified offsets.
     while (ref_offsets != 0) {
       size_t right_shift = CLZ(ref_offsets);
       MemberOffset field_offset = CLASS_OFFSET_FROM_CLZ(right_shift);
       const Object* ref = obj->GetFieldObject<const Object*>(field_offset, false);
       CheckReference(obj, ref, field_offset, is_static);
       ref_offsets &= ~(CLASS_HIGH_BIT >> right_shift);
     }
   } else {
     // There is no reference offset bitmap.  In the non-static case,
     // walk up the class inheritance hierarchy and find reference
     // offsets the hard way. In the static case, just consider this
     // class.
     for (const Class* klass = is_static ? obj->AsClass() : obj->GetClass();
          klass != NULL;
          klass = is_static ? NULL : klass->GetSuperClass()) {
       size_t num_reference_fields = (is_static
                                      ? klass->NumReferenceStaticFields()
                                      : klass->NumReferenceInstanceFields());
       for (size_t i = 0; i < num_reference_fields; ++i) {
         Field* field = (is_static
                         ? klass->GetStaticField(i)
                         : klass->GetInstanceField(i));
         MemberOffset field_offset = field->GetOffset();
         const Object* ref = obj->GetFieldObject<const Object*>(field_offset, false);
         CheckReference(obj, ref, field_offset, is_static);
       }
     }
   }
 }

 // Scans the header, static field references, and interface pointers
 // of a class object.
 inline void MarkSweep::ScanClass(const Object* obj) {
 #ifndef NDEBUG
   ++class_count_;
 #endif
   ScanInstanceFields(obj);
   ScanStaticFields(obj->AsClass());
 }

 inline void MarkSweep::CheckClass(const Object* obj) {
   CheckInstanceFields(obj);
   CheckStaticFields(obj->AsClass());
 }

 // Scans the header of all array objects.  If the array object is
 // specialized to a reference type, scans the array data as well.
 inline void MarkSweep::ScanArray(const Object* obj) {
 #ifndef NDEBUG
   ++array_count_;
 #endif
   MarkObject(obj->GetClass());
   if (obj->IsObjectArray()) {
     const ObjectArray<Object>* array = obj->AsObjectArray<Object>();
     for (int32_t i = 0; i < array->GetLength(); ++i) {
       const Object* element = array->GetWithoutChecks(i);
       MarkObject(element);
     }
   }
 }

 inline void MarkSweep::CheckArray(const Object* obj) {
   CheckReference(obj, obj->GetClass(), Object::ClassOffset(), false);
   if (obj->IsObjectArray()) {
     const ObjectArray<Object>* array = obj->AsObjectArray<Object>();
     for (int32_t i = 0; i < array->GetLength(); ++i) {
       const Object* element = array->GetWithoutChecks(i);
       size_t width = sizeof(Object*);
       CheckReference(obj, element, MemberOffset(i * width +
                                                 Array::DataOffset(width).Int32Value()), false);
     }
   }
 }

 // Process the "referent" field in a java.lang.ref.Reference.  If the
 // referent has not yet been marked, put it on the appropriate list in
 // the gcHeap for later processing.
 void MarkSweep::DelayReferenceReferent(Object* obj) {
   DCHECK(obj != NULL);
   Class* klass = obj->GetClass();
   DCHECK(klass != NULL);
   DCHECK(klass->IsReferenceClass());
   Object* pending = obj->GetFieldObject<Object*>(heap_->GetReferencePendingNextOffset(), false);
   Object* referent = heap_->GetReferenceReferent(obj);
   if (pending == NULL && referent != NULL && !IsMarked(referent)) {
     Object** list = NULL;
     if (klass->IsSoftReferenceClass()) {
       list = &soft_reference_list_;
     } else if (klass->IsWeakReferenceClass()) {
       list = &weak_reference_list_;
     } else if (klass->IsFinalizerReferenceClass()) {
       list = &finalizer_reference_list_;
     } else if (klass->IsPhantomReferenceClass()) {
       list = &phantom_reference_list_;
     }
     DCHECK(list != NULL) << PrettyClass(klass) << " " << std::hex << klass->GetAccessFlags();
     heap_->EnqueuePendingReference(obj, list);
   }
 }

 // Scans the header and field references of a data object.  If the
 // scanned object is a reference subclass, it is scheduled for later
 // processing.
 inline void MarkSweep::ScanOther(const Object* obj) {
 #ifndef NDEBUG
   ++other_count_;
 #endif
   ScanInstanceFields(obj);
   if (obj->GetClass()->IsReferenceClass()) {
     DelayReferenceReferent(const_cast<Object*>(obj));
   }
 }

 inline void MarkSweep::CheckOther(const Object* obj) {
   CheckInstanceFields(obj);
 }

 // Scans an object reference.  Determines the type of the reference
 // and dispatches to a specialized scanning routine.
 inline void MarkSweep::ScanObject(const Object* obj) {
   DCHECK(obj != NULL);
   DCHECK(obj->GetClass() != NULL);
   DCHECK(IsMarked(obj));
   if (obj->IsClass()) {
     ScanClass(obj);
   } else if (obj->IsArrayInstance()) {
     ScanArray(obj);
   } else {
     ScanOther(obj);
   }
 }

 // Check to see that all alloc space references are marked for the given object
 inline void MarkSweep::CheckObject(const Object* obj) {
   DCHECK(obj != NULL);
   DCHECK(obj->GetClass() != NULL);
   DCHECK(IsMarked(obj));
   if (obj->IsClass()) {
     CheckClass(obj);
   } else if (obj->IsArrayInstance()) {
     CheckArray(obj);
   } else {
     CheckOther(obj);
   }
 }

 // Scan anything that's on the mark stack.
 void MarkSweep::ProcessMarkStack() {
   Space* alloc_space = heap_->GetAllocSpace();
   while (!mark_stack_->IsEmpty()) {
     const Object* obj = mark_stack_->Pop();
     if (alloc_space->Contains(obj)) {
       ScanObject(obj);
     }
   }
 }

 void MarkSweep::ScanDirtyObjects() {
   ProcessMarkStack();
 }

 // Walks the reference list marking any references subject to the
 // reference clearing policy.  References with a black referent are
 // removed from the list.  References with white referents biased
 // toward saving are blackened and also removed from the list.
 void MarkSweep::PreserveSomeSoftReferences(Object** list) {
   DCHECK(list != NULL);
   Object* clear = NULL;
   size_t counter = 0;
   while (*list != NULL) {
     Object* ref = heap_->DequeuePendingReference(list);
     Object* referent = heap_->GetReferenceReferent(ref);
     if (referent == NULL) {
       // Referent was cleared by the user during marking.
       continue;
     }
     bool is_marked = IsMarked(referent);
     if (!is_marked && ((++counter) & 1)) {
       // Referent is white and biased toward saving, mark it.
       MarkObject(referent);
       is_marked = true;
     }
     if (!is_marked) {
       // Referent is white, queue it for clearing.
       heap_->EnqueuePendingReference(ref, &clear);
     }
   }
   *list = clear;
   // Restart the mark with the newly black references added to the
   // root set.
   ProcessMarkStack();
 }

 // Unlink the reference list clearing references objects with white
 // referents.  Cleared references registered to a reference queue are
 // scheduled for appending by the heap worker thread.
 void MarkSweep::ClearWhiteReferences(Object** list) {
   DCHECK(list != NULL);
   while (*list != NULL) {
     Object* ref = heap_->DequeuePendingReference(list);
     Object* referent = heap_->GetReferenceReferent(ref);
     if (referent != NULL && !IsMarked(referent)) {
       // Referent is white, clear it.
       heap_->ClearReferenceReferent(ref);
       if (heap_->IsEnqueuable(ref)) {
         heap_->EnqueueReference(ref, &cleared_reference_list_);
       }
     }
   }
   DCHECK(*list == NULL);
 }

 // Enqueues finalizer references with white referents.  White
 // referents are blackened, moved to the zombie field, and the
 // referent field is cleared.
 void MarkSweep::EnqueueFinalizerReferences(Object** list) {
   DCHECK(list != NULL);
   MemberOffset zombie_offset = heap_->GetFinalizerReferenceZombieOffset();
   bool has_enqueued = false;
   while (*list != NULL) {
     Object* ref = heap_->DequeuePendingReference(list);
     Object* referent = heap_->GetReferenceReferent(ref);
     if (referent != NULL && !IsMarked(referent)) {
       MarkObject(referent);
       // If the referent is non-null the reference must queuable.
       DCHECK(heap_->IsEnqueuable(ref));
       ref->SetFieldObject(zombie_offset, referent, false);
       heap_->ClearReferenceReferent(ref);
       heap_->EnqueueReference(ref, &cleared_reference_list_);
       has_enqueued = true;
     }
   }
   if (has_enqueued) {
     ProcessMarkStack();
   }
   DCHECK(*list == NULL);
 }

 // Process reference class instances and schedule finalizations.
 void MarkSweep::ProcessReferences(Object** soft_references, bool clear_soft,
                                   Object** weak_references,
                                   Object** finalizer_references,
                                   Object** phantom_references) {
   DCHECK(soft_references != NULL);
   DCHECK(weak_references != NULL);
   DCHECK(finalizer_references != NULL);
   DCHECK(phantom_references != NULL);

   // Unless we are in the zygote or required to clear soft references
   // with white references, preserve some white referents.
   if (clear_soft) {
     PreserveSomeSoftReferences(soft_references);
   }

   // Clear all remaining soft and weak references with white
   // referents.
   ClearWhiteReferences(soft_references);
   ClearWhiteReferences(weak_references);

   // Preserve all white objects with finalize methods and schedule
   // them for finalization.
   EnqueueFinalizerReferences(finalizer_references);

   // Clear all f-reachable soft and weak references with white
   // referents.
   ClearWhiteReferences(soft_references);
   ClearWhiteReferences(weak_references);

   // Clear all phantom references with white referents.
   ClearWhiteReferences(phantom_references);

   // At this point all reference lists should be empty.
   DCHECK(*soft_references == NULL);
   DCHECK(*weak_references == NULL);
   DCHECK(*finalizer_references == NULL);
   DCHECK(*phantom_references == NULL);
 }

 MarkSweep::~MarkSweep() {
 #ifndef NDEBUG
   VLOG(heap) << "MarkSweep scanned classes=" << class_count_ << " arrays=" << array_count_ << " other=" << other_count_;
 #endif
   delete mark_stack_;
   mark_bitmap_->Clear();
 }

 }  // namespace art
	/*
	* Copyright (C) 2011 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include "mark_sweep.h"

	#include <climits>
	#include <vector>

	#include "class_loader.h"
	#include "dex_cache.h"
	#include "heap.h"
	#include "indirect_reference_table.h"
	#include "intern_table.h"
	#include "logging.h"
	#include "macros.h"
	#include "mark_stack.h"
	#include "monitor.h"
	#include "object.h"
	#include "runtime.h"
	#include "space.h"
	#include "timing_logger.h"
	#include "thread.h"

	namespace art {

	void MarkSweep::Init() {
	mark_stack_ = MarkStack::Create();

	heap_ = Runtime::Current()->GetHeap();
	mark_bitmap_ = heap_->GetMarkBits();
	live_bitmap_ = heap_->GetLiveBits();

	// TODO: if concurrent, clear the card table.

	// TODO: if concurrent, enable card marking in compiler

	// TODO: check that the mark bitmap is entirely clear.
	}

	inline void MarkSweep::MarkObject0(const Object* obj, bool check_finger) {
	DCHECK(obj != NULL);
	if (obj < condemned_) {
	DCHECK(IsMarked(obj));
	return;
	}
	bool is_marked = mark_bitmap_->Test(obj);
	// This object was not previously marked.
	if (!is_marked) {
	mark_bitmap_->Set(obj);
	if (check_finger && obj < finger_) {
	// The object must be pushed on to the mark stack.
	mark_stack_->Push(obj);
	}
	}
	}

	// Used to mark objects when recursing. Recursion is done by moving
	// the finger across the bitmaps in address order and marking child
	// objects. Any newly-marked objects whose addresses are lower than
	// the finger won't be visited by the bitmap scan, so those objects
	// need to be added to the mark stack.
	inline void MarkSweep::MarkObject(const Object* obj) {
	if (obj != NULL) {
	MarkObject0(obj, true);
	}
	}

	void MarkSweep::MarkObjectVisitor(const Object* root, void* arg) {
	DCHECK(root != NULL);
	DCHECK(arg != NULL);
	MarkSweep* mark_sweep = reinterpret_cast<MarkSweep*>(arg);
	DCHECK(mark_sweep->finger_ == NULL); // no point to check finger if it is NULL
	mark_sweep->MarkObject0(root, false);
	}

	// Marks all objects in the root set.
	void MarkSweep::MarkRoots() {
	Runtime::Current()->VisitRoots(MarkObjectVisitor, this);
	}

	void MarkSweep::ScanImageRootVisitor(Object* root, void* arg) {
	DCHECK(root != NULL);
	DCHECK(arg != NULL);
	MarkSweep* mark_sweep = reinterpret_cast<MarkSweep*>(arg);
	DCHECK(mark_sweep->finger_ == NULL); // no point to check finger if it is NULL
	mark_sweep->MarkObject0(root, false);
	mark_sweep->ScanObject(root);
	}

	// Marks all objects that are in images and have been touched by the mutator
	void MarkSweep::ScanDirtyImageRoots() {
	const std::vector<Space*>& spaces = heap_->GetSpaces();
	CardTable* card_table = heap_->GetCardTable();
	for (size_t i = 0; i < spaces.size(); ++i) {
	if (spaces[i]->IsImageSpace()) {
	byte* begin = spaces[i]->Begin();
	byte* end = spaces[i]->End();
	card_table->Scan(begin, end, ScanImageRootVisitor, this);
	}
	}
	}

	void MarkSweep::CheckBitmapCallback(Object* obj, void* finger, void* arg) {
	MarkSweep* mark_sweep = reinterpret_cast<MarkSweep*>(arg);
	mark_sweep->finger_ = reinterpret_cast<Object*>(finger);
	mark_sweep->CheckObject(obj);
	}

	void MarkSweep::ScanBitmapCallback(Object* obj, void* finger, void* arg) {
	MarkSweep* mark_sweep = reinterpret_cast<MarkSweep*>(arg);
	mark_sweep->finger_ = reinterpret_cast<Object*>(finger);
	mark_sweep->ScanObject(obj);
	}

	// Populates the mark stack based on the set of marked objects and
	// recursively marks until the mark stack is emptied.
	void MarkSweep::RecursiveMark() {
	// RecursiveMark will build the lists of known instances of the Reference classes.
	// See DelayReferenceReferent for details.
	CHECK(soft_reference_list_ == NULL);
	CHECK(weak_reference_list_ == NULL);
	CHECK(finalizer_reference_list_ == NULL);
	CHECK(phantom_reference_list_ == NULL);
	CHECK(cleared_reference_list_ == NULL);

	void* arg = reinterpret_cast<void*>(this);
	const std::vector<Space*>& spaces = heap_->GetSpaces();
	for (size_t i = 0; i < spaces.size(); ++i) {
	#ifndef NDEBUG
	uintptr_t begin = reinterpret_cast<uintptr_t>(spaces[i]->Begin());
	uintptr_t end = reinterpret_cast<uintptr_t>(spaces[i]->End());
	if (!spaces[i]->IsImageSpace()) {
	mark_bitmap_->ScanWalk(begin, end, &MarkSweep::ScanBitmapCallback, arg);
	} else {
	mark_bitmap_->ScanWalk(begin, end, &MarkSweep::CheckBitmapCallback, arg);
	}
	#else
	if (!spaces[i]->IsImageSpace()) {
	uintptr_t begin = reinterpret_cast<uintptr_t>(spaces[i]->Begin());
	uintptr_t end = reinterpret_cast<uintptr_t>(spaces[i]->End());
	mark_bitmap_->ScanWalk(begin, end, &MarkSweep::ScanBitmapCallback, arg);
	}
	#endif
	}
	finger_ = reinterpret_cast<Object*>(~0);
	// TODO: tune the frequency of emptying the mark stack
	ProcessMarkStack();
	}

	void MarkSweep::ReMarkRoots() {
	UNIMPLEMENTED(FATAL);
	}

	void MarkSweep::SweepJniWeakGlobals() {
	JavaVMExt* vm = Runtime::Current()->GetJavaVM();
	MutexLock mu(vm->weak_globals_lock);
	IndirectReferenceTable* table = &vm->weak_globals;
	typedef IndirectReferenceTable::iterator It; // TODO: C++0x auto
	for (It it = table->begin(), end = table->end(); it != end; ++it) {
	const Object** entry = *it;
	if (!IsMarked(*entry)) {
	*entry = kClearedJniWeakGlobal;
	}
	}
	}

	void MarkSweep::SweepSystemWeaks() {
	Runtime::Current()->GetInternTable()->SweepInternTableWeaks(IsMarked, this);
	Runtime::Current()->GetMonitorList()->SweepMonitorList(IsMarked, this);
	SweepJniWeakGlobals();
	}

	struct SweepCallbackContext {
	Heap* heap;
	AllocSpace* space;
	};

	void MarkSweep::SweepCallback(size_t num_ptrs, Object** ptrs, void* arg) {
	// TODO: lock heap if concurrent
	size_t freed_objects = num_ptrs;
	size_t freed_bytes = 0;
	SweepCallbackContext* context = static_cast<SweepCallbackContext*>(arg);
	Heap* heap = context->heap;
	AllocSpace* space = context->space;
	// Use a bulk free, that merges consecutive objects before freeing or free per object?
	// Documentation suggests better free performance with merging, but this may be at the expensive
	// of allocation.
	// TODO: investigate performance
	static const bool kUseFreeList = true;
	if (kUseFreeList) {
	for (size_t i = 0; i < num_ptrs; ++i) {
	Object* obj = static_cast<Object*>(ptrs[i]);
	freed_bytes += space->AllocationSize(obj);
	heap->GetLiveBits()->Clear(obj);
	}
	// AllocSpace::FreeList clears the value in ptrs, so perform after clearing the live bit
	space->FreeList(num_ptrs, ptrs);
	} else {
	for (size_t i = 0; i < num_ptrs; ++i) {
	Object* obj = static_cast<Object*>(ptrs[i]);
	freed_bytes += space->AllocationSize(obj);
	heap->GetLiveBits()->Clear(obj);
	space->Free(obj);
	}
	}
	heap->RecordFreeLocked(freed_objects, freed_bytes);
	// TODO: unlock heap if concurrent
	}

	void MarkSweep::Sweep() {
	SweepSystemWeaks();

	const std::vector<Space*>& spaces = heap_->GetSpaces();
	SweepCallbackContext scc;
	scc.heap = heap_;
	for (size_t i = 0; i < spaces.size(); ++i) {
	if (!spaces[i]->IsImageSpace()) {
	uintptr_t begin = reinterpret_cast<uintptr_t>(spaces[i]->Begin());
	uintptr_t end = reinterpret_cast<uintptr_t>(spaces[i]->End());
	scc.space = spaces[i]->AsAllocSpace();
	HeapBitmap::SweepWalk(live_bitmap_, mark_bitmap_, begin, end,
	&MarkSweep::SweepCallback, reinterpret_cast<void*>(&scc));
	}
	}
	}

	// Scans instance fields.
	inline void MarkSweep::ScanInstanceFields(const Object* obj) {
	DCHECK(obj != NULL);
	Class* klass = obj->GetClass();
	DCHECK(klass != NULL);
	ScanFields(obj, klass->GetReferenceInstanceOffsets(), false);
	}

	inline void MarkSweep::CheckInstanceFields(const Object* obj) {
	Class* klass = obj->GetClass();
	CheckFields(obj, klass->GetReferenceInstanceOffsets(), false);
	}

	// Scans static storage on a Class.
	inline void MarkSweep::ScanStaticFields(const Class* klass) {
	DCHECK(klass != NULL);
	ScanFields(klass, klass->GetReferenceStaticOffsets(), true);
	}

	inline void MarkSweep::CheckStaticFields(const Class* klass) {
	CheckFields(klass, klass->GetReferenceStaticOffsets(), true);
	}

	inline void MarkSweep::ScanFields(const Object* obj, uint32_t ref_offsets, bool is_static) {
	if (ref_offsets != CLASS_WALK_SUPER) {
	// Found a reference offset bitmap. Mark the specified offsets.
	while (ref_offsets != 0) {
	size_t right_shift = CLZ(ref_offsets);
	MemberOffset byte_offset = CLASS_OFFSET_FROM_CLZ(right_shift);
	const Object* ref = obj->GetFieldObject<const Object*>(byte_offset, false);
	MarkObject(ref);
	ref_offsets &= ~(CLASS_HIGH_BIT >> right_shift);
	}
	} else {
	// There is no reference offset bitmap. In the non-static case,
	// walk up the class inheritance hierarchy and find reference
	// offsets the hard way. In the static case, just consider this
	// class.
	for (const Class* klass = is_static ? obj->AsClass() : obj->GetClass();
	klass != NULL;
	klass = is_static ? NULL : klass->GetSuperClass()) {
	size_t num_reference_fields = (is_static
	? klass->NumReferenceStaticFields()
	: klass->NumReferenceInstanceFields());
	for (size_t i = 0; i < num_reference_fields; ++i) {
	Field* field = (is_static
	? klass->GetStaticField(i)
	: klass->GetInstanceField(i));
	MemberOffset field_offset = field->GetOffset();
	const Object* ref = obj->GetFieldObject<const Object*>(field_offset, false);
	MarkObject(ref);
	}
	}
	}
	}

	inline void MarkSweep::CheckReference(const Object* obj, const Object* ref, MemberOffset offset, bool is_static) {
	AllocSpace* alloc_space = heap_->GetAllocSpace();
	if (alloc_space->Contains(ref)) {
	bool is_marked = mark_bitmap_->Test(ref);
	if (!is_marked) {
	LOG(INFO) << *alloc_space;
	LOG(WARNING) << (is_static ? "Static ref'" : "Instance ref'") << PrettyTypeOf(ref)
	<< "' (" << reinterpret_cast<const void*>(ref) << ") in '" << PrettyTypeOf(obj)
	<< "' (" << reinterpret_cast<const void*>(obj) << ") at offset "
	<< reinterpret_cast<void*>(offset.Int32Value()) << " wasn't marked";
	bool obj_marked = heap_->GetCardTable()->IsDirty(obj);
	if (!obj_marked) {
	LOG(WARNING) << "Object '" << PrettyTypeOf(obj) << "' "
	<< "(" << reinterpret_cast<const void*>(obj) << ") contains references to "
	<< "the alloc space, but wasn't card marked";
	}
	}
	}
	}

	inline void MarkSweep::CheckFields(const Object* obj, uint32_t ref_offsets, bool is_static) {
	if (ref_offsets != CLASS_WALK_SUPER) {
	// Found a reference offset bitmap. Mark the specified offsets.
	while (ref_offsets != 0) {
	size_t right_shift = CLZ(ref_offsets);
	MemberOffset field_offset = CLASS_OFFSET_FROM_CLZ(right_shift);
	const Object* ref = obj->GetFieldObject<const Object*>(field_offset, false);
	CheckReference(obj, ref, field_offset, is_static);
	ref_offsets &= ~(CLASS_HIGH_BIT >> right_shift);
	}
	} else {
	// There is no reference offset bitmap. In the non-static case,
	// walk up the class inheritance hierarchy and find reference
	// offsets the hard way. In the static case, just consider this
	// class.
	for (const Class* klass = is_static ? obj->AsClass() : obj->GetClass();
	klass != NULL;
	klass = is_static ? NULL : klass->GetSuperClass()) {
	size_t num_reference_fields = (is_static
	? klass->NumReferenceStaticFields()
	: klass->NumReferenceInstanceFields());
	for (size_t i = 0; i < num_reference_fields; ++i) {
	Field* field = (is_static
	? klass->GetStaticField(i)
	: klass->GetInstanceField(i));
	MemberOffset field_offset = field->GetOffset();
	const Object* ref = obj->GetFieldObject<const Object*>(field_offset, false);
	CheckReference(obj, ref, field_offset, is_static);
	}
	}
	}
	}

	// Scans the header, static field references, and interface pointers
	// of a class object.
	inline void MarkSweep::ScanClass(const Object* obj) {
	#ifndef NDEBUG
	++class_count_;
	#endif
	ScanInstanceFields(obj);
	ScanStaticFields(obj->AsClass());
	}

	inline void MarkSweep::CheckClass(const Object* obj) {
	CheckInstanceFields(obj);
	CheckStaticFields(obj->AsClass());
	}

	// Scans the header of all array objects. If the array object is
	// specialized to a reference type, scans the array data as well.
	inline void MarkSweep::ScanArray(const Object* obj) {
	#ifndef NDEBUG
	++array_count_;
	#endif
	MarkObject(obj->GetClass());
	if (obj->IsObjectArray()) {
	const ObjectArray<Object>* array = obj->AsObjectArray<Object>();
	for (int32_t i = 0; i < array->GetLength(); ++i) {
	const Object* element = array->GetWithoutChecks(i);
	MarkObject(element);
	}
	}
	}

	inline void MarkSweep::CheckArray(const Object* obj) {
	CheckReference(obj, obj->GetClass(), Object::ClassOffset(), false);
	if (obj->IsObjectArray()) {
	const ObjectArray<Object>* array = obj->AsObjectArray<Object>();
	for (int32_t i = 0; i < array->GetLength(); ++i) {
	const Object* element = array->GetWithoutChecks(i);
	size_t width = sizeof(Object*);
	CheckReference(obj, element, MemberOffset(i * width +
	Array::DataOffset(width).Int32Value()), false);
	}
	}
	}

	// Process the "referent" field in a java.lang.ref.Reference. If the
	// referent has not yet been marked, put it on the appropriate list in
	// the gcHeap for later processing.
	void MarkSweep::DelayReferenceReferent(Object* obj) {
	DCHECK(obj != NULL);
	Class* klass = obj->GetClass();
	DCHECK(klass != NULL);
	DCHECK(klass->IsReferenceClass());
	Object* pending = obj->GetFieldObject<Object*>(heap_->GetReferencePendingNextOffset(), false);
	Object* referent = heap_->GetReferenceReferent(obj);
	if (pending == NULL && referent != NULL && !IsMarked(referent)) {
	Object** list = NULL;
	if (klass->IsSoftReferenceClass()) {
	list = &soft_reference_list_;
	} else if (klass->IsWeakReferenceClass()) {
	list = &weak_reference_list_;
	} else if (klass->IsFinalizerReferenceClass()) {
	list = &finalizer_reference_list_;
	} else if (klass->IsPhantomReferenceClass()) {
	list = &phantom_reference_list_;
	}
	DCHECK(list != NULL) << PrettyClass(klass) << " " << std::hex << klass->GetAccessFlags();
	heap_->EnqueuePendingReference(obj, list);
	}
	}

	// Scans the header and field references of a data object. If the
	// scanned object is a reference subclass, it is scheduled for later
	// processing.
	inline void MarkSweep::ScanOther(const Object* obj) {
	#ifndef NDEBUG
	++other_count_;
	#endif
	ScanInstanceFields(obj);
	if (obj->GetClass()->IsReferenceClass()) {
	DelayReferenceReferent(const_cast<Object*>(obj));
	}
	}

	inline void MarkSweep::CheckOther(const Object* obj) {
	CheckInstanceFields(obj);
	}

	// Scans an object reference. Determines the type of the reference
	// and dispatches to a specialized scanning routine.
	inline void MarkSweep::ScanObject(const Object* obj) {
	DCHECK(obj != NULL);
	DCHECK(obj->GetClass() != NULL);
	DCHECK(IsMarked(obj));
	if (obj->IsClass()) {
	ScanClass(obj);
	} else if (obj->IsArrayInstance()) {
	ScanArray(obj);
	} else {
	ScanOther(obj);
	}
	}

	// Check to see that all alloc space references are marked for the given object
	inline void MarkSweep::CheckObject(const Object* obj) {
	DCHECK(obj != NULL);
	DCHECK(obj->GetClass() != NULL);
	DCHECK(IsMarked(obj));
	if (obj->IsClass()) {
	CheckClass(obj);
	} else if (obj->IsArrayInstance()) {
	CheckArray(obj);
	} else {
	CheckOther(obj);
	}
	}

	// Scan anything that's on the mark stack.
	void MarkSweep::ProcessMarkStack() {
	Space* alloc_space = heap_->GetAllocSpace();
	while (!mark_stack_->IsEmpty()) {
	const Object* obj = mark_stack_->Pop();
	if (alloc_space->Contains(obj)) {
	ScanObject(obj);
	}
	}
	}

	void MarkSweep::ScanDirtyObjects() {
	ProcessMarkStack();
	}

	// Walks the reference list marking any references subject to the
	// reference clearing policy. References with a black referent are
	// removed from the list. References with white referents biased
	// toward saving are blackened and also removed from the list.
	void MarkSweep::PreserveSomeSoftReferences(Object** list) {
	DCHECK(list != NULL);
	Object* clear = NULL;
	size_t counter = 0;
	while (*list != NULL) {
	Object* ref = heap_->DequeuePendingReference(list);
	Object* referent = heap_->GetReferenceReferent(ref);
	if (referent == NULL) {
	// Referent was cleared by the user during marking.
	continue;
	}
	bool is_marked = IsMarked(referent);
	if (!is_marked && ((++counter) & 1)) {
	// Referent is white and biased toward saving, mark it.
	MarkObject(referent);
	is_marked = true;
	}
	if (!is_marked) {
	// Referent is white, queue it for clearing.
	heap_->EnqueuePendingReference(ref, &clear);
	}
	}
	*list = clear;
	// Restart the mark with the newly black references added to the
	// root set.
	ProcessMarkStack();
	}

	// Unlink the reference list clearing references objects with white
	// referents. Cleared references registered to a reference queue are
	// scheduled for appending by the heap worker thread.
	void MarkSweep::ClearWhiteReferences(Object** list) {
	DCHECK(list != NULL);
	while (*list != NULL) {
	Object* ref = heap_->DequeuePendingReference(list);
	Object* referent = heap_->GetReferenceReferent(ref);
	if (referent != NULL && !IsMarked(referent)) {
	// Referent is white, clear it.
	heap_->ClearReferenceReferent(ref);
	if (heap_->IsEnqueuable(ref)) {
	heap_->EnqueueReference(ref, &cleared_reference_list_);
	}
	}
	}
	DCHECK(*list == NULL);
	}

	// Enqueues finalizer references with white referents. White
	// referents are blackened, moved to the zombie field, and the
	// referent field is cleared.
	void MarkSweep::EnqueueFinalizerReferences(Object** list) {
	DCHECK(list != NULL);
	MemberOffset zombie_offset = heap_->GetFinalizerReferenceZombieOffset();
	bool has_enqueued = false;
	while (*list != NULL) {
	Object* ref = heap_->DequeuePendingReference(list);
	Object* referent = heap_->GetReferenceReferent(ref);
	if (referent != NULL && !IsMarked(referent)) {
	MarkObject(referent);
	// If the referent is non-null the reference must queuable.
	DCHECK(heap_->IsEnqueuable(ref));
	ref->SetFieldObject(zombie_offset, referent, false);
	heap_->ClearReferenceReferent(ref);
	heap_->EnqueueReference(ref, &cleared_reference_list_);
	has_enqueued = true;
	}
	}
	if (has_enqueued) {
	ProcessMarkStack();
	}
	DCHECK(*list == NULL);
	}

	// Process reference class instances and schedule finalizations.
	void MarkSweep::ProcessReferences(Object** soft_references, bool clear_soft,
	Object** weak_references,
	Object** finalizer_references,
	Object** phantom_references) {
	DCHECK(soft_references != NULL);
	DCHECK(weak_references != NULL);
	DCHECK(finalizer_references != NULL);
	DCHECK(phantom_references != NULL);

	// Unless we are in the zygote or required to clear soft references
	// with white references, preserve some white referents.
	if (clear_soft) {
	PreserveSomeSoftReferences(soft_references);
	}

	// Clear all remaining soft and weak references with white
	// referents.
	ClearWhiteReferences(soft_references);
	ClearWhiteReferences(weak_references);

	// Preserve all white objects with finalize methods and schedule
	// them for finalization.
	EnqueueFinalizerReferences(finalizer_references);

	// Clear all f-reachable soft and weak references with white
	// referents.
	ClearWhiteReferences(soft_references);
	ClearWhiteReferences(weak_references);

	// Clear all phantom references with white referents.
	ClearWhiteReferences(phantom_references);

	// At this point all reference lists should be empty.
	DCHECK(*soft_references == NULL);
	DCHECK(*weak_references == NULL);
	DCHECK(*finalizer_references == NULL);
	DCHECK(*phantom_references == NULL);
	}

	MarkSweep::~MarkSweep() {
	#ifndef NDEBUG
	VLOG(heap) << "MarkSweep scanned classes=" << class_count_ << " arrays=" << array_count_ << " other=" << other_count_;
	#endif
	delete mark_stack_;
	mark_bitmap_->Clear();
	}

	} // namespace art