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// Copyright 2016 the V8 project authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef V8_HEAP_SLOT_SET_H_
#define V8_HEAP_SLOT_SET_H_
#include <map>
#include <memory>
#include <stack>
#include "src/base/atomic-utils.h"
#include "src/base/bit-field.h"
#include "src/base/bits.h"
#include "src/heap/worklist.h"
#include "src/objects/compressed-slots.h"
#include "src/objects/slots.h"
#include "src/utils/allocation.h"
#include "src/utils/utils.h"
namespace v8 {
namespace internal {
enum SlotCallbackResult { KEEP_SLOT, REMOVE_SLOT };
// Possibly empty buckets (buckets that do not contain any slots) are discovered
// by the scavenger. Buckets might become non-empty when promoting objects later
// or in another thread, so all those buckets need to be revisited.
// Track possibly empty buckets within a SlotSet in this data structure. The
// class contains a word-sized bitmap, in case more bits are needed the bitmap
// is replaced with a pointer to a malloc-allocated bitmap.
class PossiblyEmptyBuckets {
public:
PossiblyEmptyBuckets() : bitmap_(kNullAddress) {}
PossiblyEmptyBuckets(PossiblyEmptyBuckets&& other) V8_NOEXCEPT
: bitmap_(other.bitmap_) {
other.bitmap_ = kNullAddress;
}
~PossiblyEmptyBuckets() { Release(); }
void Initialize() {
bitmap_ = kNullAddress;
DCHECK(!IsAllocated());
}
void Release() {
if (IsAllocated()) {
AlignedFree(BitmapArray());
}
bitmap_ = kNullAddress;
DCHECK(!IsAllocated());
}
void Insert(size_t bucket_index, size_t buckets) {
if (IsAllocated()) {
InsertAllocated(bucket_index);
} else if (bucket_index + 1 < kBitsPerWord) {
bitmap_ |= static_cast<uintptr_t>(1) << (bucket_index + 1);
} else {
Allocate(buckets);
InsertAllocated(bucket_index);
}
}
bool Contains(size_t bucket_index) {
if (IsAllocated()) {
size_t word_idx = bucket_index / kBitsPerWord;
uintptr_t* word = BitmapArray() + word_idx;
return *word &
(static_cast<uintptr_t>(1) << (bucket_index % kBitsPerWord));
} else if (bucket_index + 1 < kBitsPerWord) {
return bitmap_ & (static_cast<uintptr_t>(1) << (bucket_index + 1));
} else {
return false;
}
}
bool IsEmpty() { return bitmap_ == kNullAddress; }
private:
Address bitmap_;
static const Address kPointerTag = 1;
static const int kWordSize = sizeof(uintptr_t);
static const int kBitsPerWord = kWordSize * kBitsPerByte;
bool IsAllocated() { return bitmap_ & kPointerTag; }
void Allocate(size_t buckets) {
DCHECK(!IsAllocated());
size_t words = WordsForBuckets(buckets);
uintptr_t* ptr = reinterpret_cast<uintptr_t*>(
AlignedAlloc(words * kWordSize, kSystemPointerSize));
ptr[0] = bitmap_ >> 1;
for (size_t word_idx = 1; word_idx < words; word_idx++) {
ptr[word_idx] = 0;
}
bitmap_ = reinterpret_cast<Address>(ptr) + kPointerTag;
DCHECK(IsAllocated());
}
void InsertAllocated(size_t bucket_index) {
DCHECK(IsAllocated());
size_t word_idx = bucket_index / kBitsPerWord;
uintptr_t* word = BitmapArray() + word_idx;
*word |= static_cast<uintptr_t>(1) << (bucket_index % kBitsPerWord);
}
static size_t WordsForBuckets(size_t buckets) {
return (buckets + kBitsPerWord - 1) / kBitsPerWord;
}
uintptr_t* BitmapArray() {
DCHECK(IsAllocated());
return reinterpret_cast<uintptr_t*>(bitmap_ & ~kPointerTag);
}
FRIEND_TEST(PossiblyEmptyBucketsTest, WordsForBuckets);
DISALLOW_COPY_AND_ASSIGN(PossiblyEmptyBuckets);
};
STATIC_ASSERT(std::is_standard_layout<PossiblyEmptyBuckets>::value);
STATIC_ASSERT(sizeof(PossiblyEmptyBuckets) == kSystemPointerSize);
// Data structure for maintaining a set of slots in a standard (non-large)
// page.
// The data structure assumes that the slots are pointer size aligned and
// splits the valid slot offset range into buckets.
// Each bucket is a bitmap with a bit corresponding to a single slot offset.
class SlotSet {
public:
enum EmptyBucketMode {
FREE_EMPTY_BUCKETS, // An empty bucket will be deallocated immediately.
KEEP_EMPTY_BUCKETS // An empty bucket will be kept.
};
SlotSet() = delete;
static SlotSet* Allocate(size_t buckets) {
// SlotSet* slot_set --+
// |
// v
// +-----------------+-------------------------+
// | initial buckets | buckets array |
// +-----------------+-------------------------+
// pointer-sized pointer-sized * buckets
//
//
// The SlotSet pointer points to the beginning of the buckets array for
// faster access in the write barrier. The number of buckets is needed for
// calculating the size of this data structure.
size_t buckets_size = buckets * sizeof(Bucket*);
size_t size = kInitialBucketsSize + buckets_size;
void* allocation = AlignedAlloc(size, kSystemPointerSize);
SlotSet* slot_set = reinterpret_cast<SlotSet*>(
reinterpret_cast<uint8_t*>(allocation) + kInitialBucketsSize);
DCHECK(
IsAligned(reinterpret_cast<uintptr_t>(slot_set), kSystemPointerSize));
#ifdef DEBUG
*slot_set->initial_buckets() = buckets;
#endif
for (size_t i = 0; i < buckets; i++) {
*slot_set->bucket(i) = nullptr;
}
return slot_set;
}
static void Delete(SlotSet* slot_set, size_t buckets) {
if (slot_set == nullptr) return;
for (size_t i = 0; i < buckets; i++) {
slot_set->ReleaseBucket(i);
}
#ifdef DEBUG
size_t initial_buckets = *slot_set->initial_buckets();
for (size_t i = buckets; i < initial_buckets; i++) {
DCHECK_NULL(*slot_set->bucket(i));
}
#endif
AlignedFree(reinterpret_cast<uint8_t*>(slot_set) - kInitialBucketsSize);
}
static size_t BucketsForSize(size_t size) {
return (size + (kTaggedSize * kBitsPerBucket) - 1) >>
(kTaggedSizeLog2 + kBitsPerBucketLog2);
}
// Converts the slot offset into bucket index.
static size_t BucketForSlot(size_t slot_offset) {
DCHECK(IsAligned(slot_offset, kTaggedSize));
return slot_offset >> (kTaggedSizeLog2 + kBitsPerBucketLog2);
}
// The slot offset specifies a slot at address page_start_ + slot_offset.
// AccessMode defines whether there can be concurrent access on the buckets
// or not.
template <AccessMode access_mode>
void Insert(size_t slot_offset) {
size_t bucket_index;
int cell_index, bit_index;
SlotToIndices(slot_offset, &bucket_index, &cell_index, &bit_index);
Bucket* bucket = LoadBucket<access_mode>(bucket_index);
if (bucket == nullptr) {
bucket = new Bucket;
if (!SwapInNewBucket<access_mode>(bucket_index, bucket)) {
delete bucket;
bucket = LoadBucket<access_mode>(bucket_index);
}
}
// Check that monotonicity is preserved, i.e., once a bucket is set we do
// not free it concurrently.
DCHECK(bucket != nullptr);
DCHECK_EQ(bucket->cells(), LoadBucket<access_mode>(bucket_index)->cells());
uint32_t mask = 1u << bit_index;
if ((bucket->LoadCell<access_mode>(cell_index) & mask) == 0) {
bucket->SetCellBits<access_mode>(cell_index, mask);
}
}
// The slot offset specifies a slot at address page_start_ + slot_offset.
// Returns true if the set contains the slot.
bool Contains(size_t slot_offset) {
size_t bucket_index;
int cell_index, bit_index;
SlotToIndices(slot_offset, &bucket_index, &cell_index, &bit_index);
Bucket* bucket = LoadBucket(bucket_index);
if (bucket == nullptr) return false;
return (bucket->LoadCell(cell_index) & (1u << bit_index)) != 0;
}
// The slot offset specifies a slot at address page_start_ + slot_offset.
void Remove(size_t slot_offset) {
size_t bucket_index;
int cell_index, bit_index;
SlotToIndices(slot_offset, &bucket_index, &cell_index, &bit_index);
Bucket* bucket = LoadBucket(bucket_index);
if (bucket != nullptr) {
uint32_t cell = bucket->LoadCell(cell_index);
uint32_t bit_mask = 1u << bit_index;
if (cell & bit_mask) {
bucket->ClearCellBits(cell_index, bit_mask);
}
}
}
// The slot offsets specify a range of slots at addresses:
// [page_start_ + start_offset ... page_start_ + end_offset).
void RemoveRange(size_t start_offset, size_t end_offset, size_t buckets,
EmptyBucketMode mode) {
CHECK_LE(end_offset, buckets * kBitsPerBucket * kTaggedSize);
DCHECK_LE(start_offset, end_offset);
size_t start_bucket;
int start_cell, start_bit;
SlotToIndices(start_offset, &start_bucket, &start_cell, &start_bit);
size_t end_bucket;
int end_cell, end_bit;
SlotToIndices(end_offset, &end_bucket, &end_cell, &end_bit);
uint32_t start_mask = (1u << start_bit) - 1;
uint32_t end_mask = ~((1u << end_bit) - 1);
Bucket* bucket;
if (start_bucket == end_bucket && start_cell == end_cell) {
bucket = LoadBucket(start_bucket);
if (bucket != nullptr) {
bucket->ClearCellBits(start_cell, ~(start_mask | end_mask));
}
return;
}
size_t current_bucket = start_bucket;
int current_cell = start_cell;
bucket = LoadBucket(current_bucket);
if (bucket != nullptr) {
bucket->ClearCellBits(current_cell, ~start_mask);
}
current_cell++;
if (current_bucket < end_bucket) {
if (bucket != nullptr) {
ClearBucket(bucket, current_cell, kCellsPerBucket);
}
// The rest of the current bucket is cleared.
// Move on to the next bucket.
current_bucket++;
current_cell = 0;
}
DCHECK(current_bucket == end_bucket ||
(current_bucket < end_bucket && current_cell == 0));
while (current_bucket < end_bucket) {
if (mode == FREE_EMPTY_BUCKETS) {
ReleaseBucket(current_bucket);
} else {
DCHECK(mode == KEEP_EMPTY_BUCKETS);
bucket = LoadBucket(current_bucket);
if (bucket != nullptr) {
ClearBucket(bucket, 0, kCellsPerBucket);
}
}
current_bucket++;
}
// All buckets between start_bucket and end_bucket are cleared.
DCHECK(current_bucket == end_bucket);
if (current_bucket == buckets) return;
bucket = LoadBucket(current_bucket);
DCHECK(current_cell <= end_cell);
if (bucket == nullptr) return;
while (current_cell < end_cell) {
bucket->StoreCell(current_cell, 0);
current_cell++;
}
// All cells between start_cell and end_cell are cleared.
DCHECK(current_bucket == end_bucket && current_cell == end_cell);
bucket->ClearCellBits(end_cell, ~end_mask);
}
// The slot offset specifies a slot at address page_start_ + slot_offset.
bool Lookup(size_t slot_offset) {
size_t bucket_index;
int cell_index, bit_index;
SlotToIndices(slot_offset, &bucket_index, &cell_index, &bit_index);
Bucket* bucket = LoadBucket(bucket_index);
if (bucket == nullptr) return false;
return (bucket->LoadCell(cell_index) & (1u << bit_index)) != 0;
}
// Iterate over all slots in the set and for each slot invoke the callback.
// If the callback returns REMOVE_SLOT then the slot is removed from the set.
// Returns the new number of slots.
//
// Iteration can be performed concurrently with other operations that use
// atomic access mode such as insertion and removal. However there is no
// guarantee about ordering and linearizability.
//
// Sample usage:
// Iterate([](MaybeObjectSlot slot) {
// if (good(slot)) return KEEP_SLOT;
// else return REMOVE_SLOT;
// });
//
// Releases memory for empty buckets with FREE_EMPTY_BUCKETS.
template <typename Callback>
size_t Iterate(Address chunk_start, size_t start_bucket, size_t end_bucket,
Callback callback, EmptyBucketMode mode) {
return Iterate(chunk_start, start_bucket, end_bucket, callback,
[this, mode](size_t bucket_index) {
if (mode == EmptyBucketMode::FREE_EMPTY_BUCKETS) {
ReleaseBucket(bucket_index);
}
});
}
// Similar to Iterate but marks potentially empty buckets internally. Stores
// true in empty_bucket_found in case a potentially empty bucket was found.
// Assumes that the possibly empty-array was already cleared by
// CheckPossiblyEmptyBuckets.
template <typename Callback>
size_t IterateAndTrackEmptyBuckets(
Address chunk_start, size_t start_bucket, size_t end_bucket,
Callback callback, PossiblyEmptyBuckets* possibly_empty_buckets) {
return Iterate(chunk_start, start_bucket, end_bucket, callback,
[possibly_empty_buckets, end_bucket](size_t bucket_index) {
possibly_empty_buckets->Insert(bucket_index, end_bucket);
});
}
bool FreeEmptyBuckets(size_t buckets) {
bool empty = true;
for (size_t bucket_index = 0; bucket_index < buckets; bucket_index++) {
if (!FreeBucketIfEmpty(bucket_index)) {
empty = false;
}
}
return empty;
}
// Check whether possibly empty buckets are really empty. Empty buckets are
// freed and the possibly empty state is cleared for all buckets.
bool CheckPossiblyEmptyBuckets(size_t buckets,
PossiblyEmptyBuckets* possibly_empty_buckets) {
bool empty = true;
for (size_t bucket_index = 0; bucket_index < buckets; bucket_index++) {
Bucket* bucket = LoadBucket<AccessMode::NON_ATOMIC>(bucket_index);
if (bucket) {
if (possibly_empty_buckets->Contains(bucket_index)) {
if (bucket->IsEmpty()) {
ReleaseBucket<AccessMode::NON_ATOMIC>(bucket_index);
} else {
empty = false;
}
} else {
empty = false;
}
} else {
// Unfortunately we cannot DCHECK here that the corresponding bit in
// possibly_empty_buckets is not set. After scavenge, the
// MergeOldToNewRememberedSets operation might remove a recorded bucket.
}
}
possibly_empty_buckets->Release();
return empty;
}
static const int kCellsPerBucket = 32;
static const int kCellsPerBucketLog2 = 5;
static const int kCellSizeBytesLog2 = 2;
static const int kCellSizeBytes = 1 << kCellSizeBytesLog2;
static const int kBitsPerCell = 32;
static const int kBitsPerCellLog2 = 5;
static const int kBitsPerBucket = kCellsPerBucket * kBitsPerCell;
static const int kBitsPerBucketLog2 = kCellsPerBucketLog2 + kBitsPerCellLog2;
static const int kBucketsRegularPage =
(1 << kPageSizeBits) / kTaggedSize / kCellsPerBucket / kBitsPerCell;
class Bucket : public Malloced {
uint32_t cells_[kCellsPerBucket];
public:
Bucket() {
for (int i = 0; i < kCellsPerBucket; i++) {
cells_[i] = 0;
}
}
uint32_t* cells() { return cells_; }
uint32_t* cell(int cell_index) { return cells() + cell_index; }
template <AccessMode access_mode = AccessMode::ATOMIC>
uint32_t LoadCell(int cell_index) {
DCHECK_LT(cell_index, kCellsPerBucket);
if (access_mode == AccessMode::ATOMIC)
return base::AsAtomic32::Acquire_Load(cells() + cell_index);
return *(cells() + cell_index);
}
template <AccessMode access_mode = AccessMode::ATOMIC>
void SetCellBits(int cell_index, uint32_t mask) {
if (access_mode == AccessMode::ATOMIC) {
base::AsAtomic32::SetBits(cell(cell_index), mask, mask);
} else {
uint32_t* c = cell(cell_index);
*c = (*c & ~mask) | mask;
}
}
void ClearCellBits(int cell_index, uint32_t mask) {
base::AsAtomic32::SetBits(cell(cell_index), 0u, mask);
}
void StoreCell(int cell_index, uint32_t value) {
base::AsAtomic32::Release_Store(cell(cell_index), value);
}
bool IsEmpty() {
for (int i = 0; i < kCellsPerBucket; i++) {
if (cells_[i] != 0) {
return false;
}
}
return true;
}
};
private:
template <typename Callback, typename EmptyBucketCallback>
size_t Iterate(Address chunk_start, size_t start_bucket, size_t end_bucket,
Callback callback, EmptyBucketCallback empty_bucket_callback) {
size_t new_count = 0;
for (size_t bucket_index = start_bucket; bucket_index < end_bucket;
bucket_index++) {
Bucket* bucket = LoadBucket(bucket_index);
if (bucket != nullptr) {
size_t in_bucket_count = 0;
size_t cell_offset = bucket_index << kBitsPerBucketLog2;
for (int i = 0; i < kCellsPerBucket; i++, cell_offset += kBitsPerCell) {
uint32_t cell = bucket->LoadCell(i);
if (cell) {
uint32_t old_cell = cell;
uint32_t mask = 0;
while (cell) {
int bit_offset = base::bits::CountTrailingZeros(cell);
uint32_t bit_mask = 1u << bit_offset;
Address slot = (cell_offset + bit_offset) << kTaggedSizeLog2;
if (callback(MaybeObjectSlot(chunk_start + slot)) == KEEP_SLOT) {
++in_bucket_count;
} else {
mask |= bit_mask;
}
cell ^= bit_mask;
}
uint32_t new_cell = old_cell & ~mask;
if (old_cell != new_cell) {
bucket->ClearCellBits(i, mask);
}
}
}
if (in_bucket_count == 0) {
empty_bucket_callback(bucket_index);
}
new_count += in_bucket_count;
}
}
return new_count;
}
bool FreeBucketIfEmpty(size_t bucket_index) {
Bucket* bucket = LoadBucket<AccessMode::NON_ATOMIC>(bucket_index);
if (bucket != nullptr) {
if (bucket->IsEmpty()) {
ReleaseBucket<AccessMode::NON_ATOMIC>(bucket_index);
} else {
return false;
}
}
return true;
}
void ClearBucket(Bucket* bucket, int start_cell, int end_cell) {
DCHECK_GE(start_cell, 0);
DCHECK_LE(end_cell, kCellsPerBucket);
int current_cell = start_cell;
while (current_cell < kCellsPerBucket) {
bucket->StoreCell(current_cell, 0);
current_cell++;
}
}
template <AccessMode access_mode = AccessMode::ATOMIC>
void ReleaseBucket(size_t bucket_index) {
Bucket* bucket = LoadBucket<access_mode>(bucket_index);
StoreBucket<access_mode>(bucket_index, nullptr);
delete bucket;
}
template <AccessMode access_mode = AccessMode::ATOMIC>
Bucket* LoadBucket(Bucket** bucket) {
if (access_mode == AccessMode::ATOMIC)
return base::AsAtomicPointer::Acquire_Load(bucket);
return *bucket;
}
template <AccessMode access_mode = AccessMode::ATOMIC>
Bucket* LoadBucket(size_t bucket_index) {
return LoadBucket(bucket(bucket_index));
}
template <AccessMode access_mode = AccessMode::ATOMIC>
void StoreBucket(Bucket** bucket, Bucket* value) {
if (access_mode == AccessMode::ATOMIC) {
base::AsAtomicPointer::Release_Store(bucket, value);
} else {
*bucket = value;
}
}
template <AccessMode access_mode = AccessMode::ATOMIC>
void StoreBucket(size_t bucket_index, Bucket* value) {
StoreBucket(bucket(bucket_index), value);
}
template <AccessMode access_mode = AccessMode::ATOMIC>
bool SwapInNewBucket(size_t bucket_index, Bucket* value) {
Bucket** b = bucket(bucket_index);
if (access_mode == AccessMode::ATOMIC) {
return base::AsAtomicPointer::Release_CompareAndSwap(b, nullptr, value) ==
nullptr;
} else {
DCHECK_NULL(*b);
*b = value;
return true;
}
}
// Converts the slot offset into bucket/cell/bit index.
static void SlotToIndices(size_t slot_offset, size_t* bucket_index,
int* cell_index, int* bit_index) {
DCHECK(IsAligned(slot_offset, kTaggedSize));
size_t slot = slot_offset >> kTaggedSizeLog2;
*bucket_index = slot >> kBitsPerBucketLog2;
*cell_index =
static_cast<int>((slot >> kBitsPerCellLog2) & (kCellsPerBucket - 1));
*bit_index = static_cast<int>(slot & (kBitsPerCell - 1));
}
Bucket** buckets() { return reinterpret_cast<Bucket**>(this); }
Bucket** bucket(size_t bucket_index) { return buckets() + bucket_index; }
#ifdef DEBUG
size_t* initial_buckets() { return reinterpret_cast<size_t*>(this) - 1; }
static const int kInitialBucketsSize = sizeof(size_t);
#else
static const int kInitialBucketsSize = 0;
#endif
};
STATIC_ASSERT(std::is_standard_layout<SlotSet>::value);
STATIC_ASSERT(std::is_standard_layout<SlotSet::Bucket>::value);
enum SlotType {
FULL_EMBEDDED_OBJECT_SLOT,
COMPRESSED_EMBEDDED_OBJECT_SLOT,
FULL_OBJECT_SLOT,
COMPRESSED_OBJECT_SLOT,
CODE_TARGET_SLOT,
CODE_ENTRY_SLOT,
CLEARED_SLOT
};
// Data structure for maintaining a list of typed slots in a page.
// Typed slots can only appear in Code objects, so
// the maximum possible offset is limited by the LargePage::kMaxCodePageSize.
// The implementation is a chain of chunks, where each chunk is an array of
// encoded (slot type, slot offset) pairs.
// There is no duplicate detection and we do not expect many duplicates because
// typed slots contain V8 internal pointers that are not directly exposed to JS.
class V8_EXPORT_PRIVATE TypedSlots {
public:
static const int kMaxOffset = 1 << 29;
TypedSlots() = default;
virtual ~TypedSlots();
void Insert(SlotType type, uint32_t offset);
void Merge(TypedSlots* other);
protected:
using OffsetField = base::BitField<int, 0, 29>;
using TypeField = base::BitField<SlotType, 29, 3>;
struct TypedSlot {
uint32_t type_and_offset;
};
struct Chunk {
Chunk* next;
std::vector<TypedSlot> buffer;
};
static const size_t kInitialBufferSize = 100;
static const size_t kMaxBufferSize = 16 * KB;
static size_t NextCapacity(size_t capacity) {
return Min(kMaxBufferSize, capacity * 2);
}
Chunk* EnsureChunk();
Chunk* NewChunk(Chunk* next, size_t capacity);
Chunk* head_ = nullptr;
Chunk* tail_ = nullptr;
};
// A multiset of per-page typed slots that allows concurrent iteration
// clearing of invalid slots.
class V8_EXPORT_PRIVATE TypedSlotSet : public TypedSlots {
public:
enum IterationMode { FREE_EMPTY_CHUNKS, KEEP_EMPTY_CHUNKS };
explicit TypedSlotSet(Address page_start) : page_start_(page_start) {}
// Iterate over all slots in the set and for each slot invoke the callback.
// If the callback returns REMOVE_SLOT then the slot is removed from the set.
// Returns the new number of slots.
//
// Sample usage:
// Iterate([](SlotType slot_type, Address slot_address) {
// if (good(slot_type, slot_address)) return KEEP_SLOT;
// else return REMOVE_SLOT;
// });
// This can run concurrently to ClearInvalidSlots().
template <typename Callback>
int Iterate(Callback callback, IterationMode mode) {
STATIC_ASSERT(CLEARED_SLOT < 8);
Chunk* chunk = head_;
Chunk* previous = nullptr;
int new_count = 0;
while (chunk != nullptr) {
bool empty = true;
for (TypedSlot& slot : chunk->buffer) {
SlotType type = TypeField::decode(slot.type_and_offset);
if (type != CLEARED_SLOT) {
uint32_t offset = OffsetField::decode(slot.type_and_offset);
Address addr = page_start_ + offset;
if (callback(type, addr) == KEEP_SLOT) {
new_count++;
empty = false;
} else {
slot = ClearedTypedSlot();
}
}
}
Chunk* next = chunk->next;
if (mode == FREE_EMPTY_CHUNKS && empty) {
// We remove the chunk from the list but let it still point its next
// chunk to allow concurrent iteration.
if (previous) {
StoreNext(previous, next);
} else {
StoreHead(next);
}
delete chunk;
} else {
previous = chunk;
}
chunk = next;
}
return new_count;
}
// Clears all slots that have the offset in the specified ranges.
// This can run concurrently to Iterate().
void ClearInvalidSlots(const std::map<uint32_t, uint32_t>& invalid_ranges);
// Frees empty chunks accumulated by PREFREE_EMPTY_CHUNKS.
void FreeToBeFreedChunks();
private:
// Atomic operations used by Iterate and ClearInvalidSlots;
Chunk* LoadNext(Chunk* chunk) {
return base::AsAtomicPointer::Relaxed_Load(&chunk->next);
}
void StoreNext(Chunk* chunk, Chunk* next) {
return base::AsAtomicPointer::Relaxed_Store(&chunk->next, next);
}
Chunk* LoadHead() { return base::AsAtomicPointer::Relaxed_Load(&head_); }
void StoreHead(Chunk* chunk) {
base::AsAtomicPointer::Relaxed_Store(&head_, chunk);
}
static TypedSlot ClearedTypedSlot() {
return TypedSlot{TypeField::encode(CLEARED_SLOT) | OffsetField::encode(0)};
}
Address page_start_;
};
} // namespace internal
} // namespace v8
#endif // V8_HEAP_SLOT_SET_H_