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LeafOS / LeafOS-Project / android_art / b984ded74d1e03e5a515cd003c0586de1388346f / . / src / mark_sweep.cc
blob: d2e7b66eff8153a2aa2c9b36226b3a93ce3a3976 [file] [log] [blame]
// Copyright 2011 Google Inc. All Rights Reserved.
// Author: cshapiro@google.com (Carl Shapiro)
#include "mark_sweep.h"
#include "logging.h"
#include "macros.h"
#include "mark_stack.h"
#include "object.h"
#include "thread.h"
#define CLZ(x) __builtin_clz(x)
namespace art {
size_t MarkSweep::reference_referent_offset_ = 0; // TODO
size_t MarkSweep::reference_queue_offset_ = 0; // TODO
size_t MarkSweep::reference_queueNext_offset_ = 0; // TODO
size_t MarkSweep::reference_pendingNext_offset_ = 0; // TODO
size_t MarkSweep::finalizer_reference_zombie_offset_ = 0; // TODO
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.
void MarkSweep::MarkObject(const Object* obj) {
if (obj != NULL) {
MarkObject0(obj, true);
}
}
// Marks all objects in the root set.
void MarkSweep::MarkRoots() {
LOG(FATAL) << "Unimplemented";
}
void MarkSweep::ReMarkRoots()
{
LOG(FATAL) << "Unimplemented";
}
// Scans instance fields.
void MarkSweep::ScanInstanceFields(const Object* obj) {
DCHECK(obj != NULL);
DCHECK(obj->GetClass() != NULL);
uint32_t ref_offsets = obj->GetClass()->GetReferenceOffsets();
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);
size_t byte_offset = CLASS_OFFSET_FROM_CLZ(right_shift);
const Object* ref = obj->GetFieldObject(byte_offset);
MarkObject(ref);
ref_offsets &= ~(CLASS_HIGH_BIT >> right_shift);
}
} else {
// There is no reference offset bitmap for this class. Walk up
// the class inheritance hierarchy and find reference offsets the
// hard way.
for (Class *klass = obj->GetClass();
klass != NULL;
klass = klass->GetSuperClass()) {
for (size_t i = 0; i < klass->NumReferenceInstanceFields(); ++i) {
size_t field_offset = klass->GetInstanceField(i)->GetOffset();
const Object* ref = obj->GetFieldObject(field_offset);
MarkObject(ref);
}
}
}
}
// Scans the static fields of a class object.
void MarkSweep::ScanStaticFields(const Class* klass) {
DCHECK(klass != NULL);
for (size_t i = 0; i < klass->NumStaticFields(); ++i) {
// char ch = clazz->sfields[i].signature[0];
const StaticField* static_field = klass->GetStaticField(i);
char ch = static_field->GetType();
if (ch == '[' || ch == 'L') {
// Object *obj = clazz->sfields[i].value.l;
// markObject(obj, ctx);
const Object* obj = static_field->GetObject();
MarkObject(obj);
}
}
}
void MarkSweep::ScanInterfaces(const Class* klass) {
DCHECK(klass != NULL);
for (size_t i = 0; i < klass->NumInterfaces(); ++i) {
MarkObject(klass->GetInterface(i));
}
}
// Scans the header, static field references, and interface pointers
// of a class object.
void MarkSweep::ScanClass(const Object* obj) {
DCHECK(obj != NULL);
DCHECK(obj->IsClass());
const Class* klass = obj->AsClass();
MarkObject(klass->GetClass());
if (klass->IsArray()) {
MarkObject(klass->GetComponentType());
}
if (klass->IsLoaded()) {
MarkObject(klass->GetSuperClass());
}
MarkObject(klass->GetClassLoader());
ScanInstanceFields(obj);
ScanStaticFields(klass);
// TODO: scan methods
// TODO: scan instance fields
if (klass->IsLoaded()) {
ScanInterfaces(klass);
}
}
// Scans the header of all array objects. If the array object is
// specialized to a reference type, scans the array data as well.
void MarkSweep::ScanArray(const Object *obj) {
DCHECK(obj != NULL);
DCHECK(obj->GetClass() != NULL);
MarkObject(obj->GetClass());
if (obj->IsObjectArray()) {
const ObjectArray* array = obj->AsObjectArray();
for (size_t i = 0; i < array->GetLength(); ++i) {
const Object* element = array->Get(i);
MarkObject(element);
}
}
}
void MarkSweep::EnqueuePendingReference(Object* ref, Object** list) {
DCHECK(ref != NULL);
DCHECK(list != NULL);
size_t offset = reference_pendingNext_offset_;
if (*list == NULL) {
ref->SetFieldObject(offset, ref);
*list = ref;
} else {
Object *head = (*list)->GetFieldObject(offset);
ref->SetFieldObject(offset, head);
(*list)->SetFieldObject(offset, ref);
}
}
Object* MarkSweep::DequeuePendingReference(Object** list) {
DCHECK(list != NULL);
DCHECK(*list != NULL);
size_t offset = reference_pendingNext_offset_;
Object* head = (*list)->GetFieldObject(offset);
Object* ref;
if (*list == head) {
ref = *list;
*list = NULL;
} else {
Object *next = head->GetFieldObject(offset);
(*list)->SetFieldObject(offset, next);
ref = head;
}
ref->SetFieldObject(offset, NULL);
return ref;
}
// 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);
DCHECK(obj->GetClass() != NULL);
//DCHECK(IS_CLASS_FLAG_SET(obj->clazz, CLASS_ISREFERENCE));
Object* pending = obj->GetFieldObject(reference_pendingNext_offset_);
Object* referent = obj->GetFieldObject(reference_referent_offset_);
if (pending == NULL && referent != NULL && !IsMarked(referent)) {
Object **list = NULL;
if (obj->IsSoftReference()) {
list = &soft_reference_list_;
} else if (obj->IsWeakReference()) {
list = &weak_reference_list_;
} else if (obj->IsFinalizerReference()) {
list = &finalizer_reference_list_;
} else if (obj->IsPhantomReference()) {
list = &phantom_reference_list_;
}
DCHECK(list != NULL);
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
void MarkSweep::ScanDataObject(const Object *obj) {
DCHECK(obj != NULL);
DCHECK(obj->GetClass() != NULL);
MarkObject(obj->GetClass());
ScanInstanceFields(obj);
if (obj->IsReference()) {
DelayReferenceReferent(const_cast<Object*>(obj));
}
}
// Scans an object reference. Determines the type of the reference
// and dispatches to a specialized scanning routine.
void MarkSweep::ScanObject(const Object* obj) {
DCHECK(obj != NULL);
DCHECK(obj->GetClass() != NULL);
DCHECK(IsMarked(obj));
if (obj->IsClass()) {
ScanClass(obj);
} else if (obj->IsArray()) {
ScanArray(obj);
} else {
ScanDataObject(obj);
}
}
// Scan anything that's on the mark stack. We can't use the bitmaps
// anymore, so use a finger that points past the end of them.
void MarkSweep::ProcessMarkStack() {
while (!mark_stack_->IsEmpty()) {
const Object *obj = mark_stack_->Pop();
ScanObject(obj);
}
}
void MarkSweep::ScanDirtyObjects() {
ProcessMarkStack();
}
void MarkSweep::ClearReference(Object* ref) {
DCHECK(ref != NULL);
ref->SetFieldObject(reference_referent_offset_, NULL);
}
bool MarkSweep::IsEnqueuable(const Object* ref) {
DCHECK(ref != NULL);
const Object* queue = ref->GetFieldObject(reference_queue_offset_);
const Object* queue_next = ref->GetFieldObject(reference_queueNext_offset_);
return (queue != NULL) && (queue_next == NULL);
}
void MarkSweep::EnqueueReference(Object* ref) {
DCHECK(ref != NULL);
CHECK(ref->GetFieldObject(reference_queue_offset_) != NULL);
CHECK(ref->GetFieldObject(reference_queueNext_offset_) == NULL);
EnqueuePendingReference(ref, &cleared_reference_list_);
}
// 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 = DequeuePendingReference(list);
Object* referent = ref->GetFieldObject(reference_referent_offset_);
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.
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);
size_t offset = reference_referent_offset_;
while (*list != NULL) {
Object *ref = DequeuePendingReference(list);
Object *referent = ref->GetFieldObject(offset);
if (referent != NULL && !IsMarked(referent)) {
// Referent is white, clear it.
ClearReference(ref);
if (IsEnqueuable(ref)) {
EnqueueReference(ref);
}
}
}
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);
size_t referent_offset = reference_referent_offset_;
size_t zombie_offset = finalizer_reference_zombie_offset_;
bool has_enqueued = false;
while (*list != NULL) {
Object* ref = DequeuePendingReference(list);
Object* referent = ref->GetFieldObject(referent_offset);
if (referent != NULL && !IsMarked(referent)) {
MarkObject(referent);
// If the referent is non-null the reference must queuable.
DCHECK(IsEnqueuable(ref));
ref->SetFieldObject(zombie_offset, referent);
ClearReference(ref);
EnqueueReference(ref);
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);
}
// Pushes a list of cleared references out to the managed heap.
void MarkSweep::EnqueueClearedReferences(Object** cleared) {
DCHECK(cleared != NULL);
if (*cleared != NULL) {
Thread* self = Thread::Current();
DCHECK(self != NULL);
// TODO: Method *meth = gDvm.methJavaLangRefReferenceQueueAdd;
// DCHECK(meth != NULL);
// JValue unused;
// Object *reference = *cleared;
// TODO: dvmCallMethod(self, meth, NULL, &unused, reference);
LOG(FATAL) << "Unimplemented";
*cleared = NULL;
}
}
MarkSweep::~MarkSweep() {
mark_bitmap_->Clear();
}
} // namespace art