DEV/flutter_flutter
1
0
Fork 0
mirror of https://github.com/flutter/flutter.git synced 2026-02-20 02:29:02 +08:00
Code Issues Packages Projects Releases Wiki Activity
flutter_flutter/engine/platform/heap/Heap.cpp
Adam Barth ae72930937 Open the Sky
2014-10-23 11:17:19 -07:00

2821 lines
97 KiB
C++
Raw Blame History

/*
* Copyright (C) 2013 Google Inc. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following disclaimer
* in the documentation and/or other materials provided with the
* distribution.
* * Neither the name of Google Inc. nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include "platform/heap/Heap.h"
#include "platform/ScriptForbiddenScope.h"
#include "platform/TraceEvent.h"
#include "platform/heap/ThreadState.h"
#include "public/platform/Platform.h"
#include "wtf/AddressSpaceRandomization.h"
#include "wtf/Assertions.h"
#include "wtf/LeakAnnotations.h"
#include "wtf/PassOwnPtr.h"
#if ENABLE(GC_PROFILE_MARKING)
#include "wtf/HashMap.h"
#include "wtf/HashSet.h"
#include "wtf/text/StringBuilder.h"
#include "wtf/text/StringHash.h"
#include <stdio.h>
#include <utility>
#endif
#if ENABLE(GC_PROFILE_HEAP)
#include "platform/TracedValue.h"
#endif
#include <sys/mman.h>
#include <unistd.h>
namespace blink {
#if ENABLE(GC_PROFILE_MARKING)
static String classOf(const void* object)
{
const GCInfo* gcInfo = Heap::findGCInfo(reinterpret_cast<Address>(const_cast<void*>(object)));
if (gcInfo)
return gcInfo->m_className;
return "unknown";
}
#endif
static bool vTableInitialized(void* objectPointer)
{
return !!(*reinterpret_cast<Address*>(objectPointer));
}
static Address roundToBlinkPageBoundary(void* base)
{
return reinterpret_cast<Address>((reinterpret_cast<uintptr_t>(base) + blinkPageOffsetMask) & blinkPageBaseMask);
}
static size_t roundToOsPageSize(size_t size)
{
return (size + osPageSize() - 1) & ~(osPageSize() - 1);
}
size_t osPageSize()
{
#if OS(POSIX)
static const size_t pageSize = getpagesize();
#else
static size_t pageSize = 0;
if (!pageSize) {
SYSTEM_INFO info;
GetSystemInfo(&info);
pageSize = info.dwPageSize;
ASSERT(IsPowerOf2(pageSize));
}
#endif
return pageSize;
}
class MemoryRegion {
public:
MemoryRegion(Address base, size_t size)
: m_base(base)
, m_size(size)
{
ASSERT(size > 0);
}
bool contains(Address addr) const
{
return m_base <= addr && addr < (m_base + m_size);
}
bool contains(const MemoryRegion& other) const
{
return contains(other.m_base) && contains(other.m_base + other.m_size - 1);
}
void release()
{
#if OS(POSIX)
int err = munmap(m_base, m_size);
RELEASE_ASSERT(!err);
#else
bool success = VirtualFree(m_base, 0, MEM_RELEASE);
RELEASE_ASSERT(success);
#endif
}
WARN_UNUSED_RETURN bool commit()
{
ASSERT(Heap::heapDoesNotContainCacheIsEmpty());
#if OS(POSIX)
int err = mprotect(m_base, m_size, PROT_READ | PROT_WRITE);
if (!err) {
madvise(m_base, m_size, MADV_NORMAL);
return true;
}
return false;
#else
void* result = VirtualAlloc(m_base, m_size, MEM_COMMIT, PAGE_READWRITE);
return !!result;
#endif
}
void decommit()
{
#if OS(POSIX)
int err = mprotect(m_base, m_size, PROT_NONE);
RELEASE_ASSERT(!err);
// FIXME: Consider using MADV_FREE on MacOS.
madvise(m_base, m_size, MADV_DONTNEED);
#else
bool success = VirtualFree(m_base, m_size, MEM_DECOMMIT);
RELEASE_ASSERT(success);
#endif
}
Address base() const { return m_base; }
size_t size() const { return m_size; }
private:
Address m_base;
size_t m_size;
};
// A PageMemoryRegion represents a chunk of reserved virtual address
// space containing a number of blink heap pages. On Windows, reserved
// virtual address space can only be given back to the system as a
// whole. The PageMemoryRegion allows us to do that by keeping track
// of the number of pages using it in order to be able to release all
// of the virtual address space when there are no more pages using it.
class PageMemoryRegion : public MemoryRegion {
public:
~PageMemoryRegion()
{
release();
}
void pageRemoved()
{
if (!--m_numPages)
delete this;
}
static PageMemoryRegion* allocate(size_t size, unsigned numPages)
{
ASSERT(Heap::heapDoesNotContainCacheIsEmpty());
// Compute a random blink page aligned address for the page memory
// region and attempt to get the memory there.
Address randomAddress = reinterpret_cast<Address>(WTF::getRandomPageBase());
Address alignedRandomAddress = roundToBlinkPageBoundary(randomAddress);
#if OS(POSIX)
Address base = static_cast<Address>(mmap(alignedRandomAddress, size, PROT_NONE, MAP_ANON | MAP_PRIVATE, -1, 0));
RELEASE_ASSERT(base != MAP_FAILED);
if (base == roundToBlinkPageBoundary(base))
return new PageMemoryRegion(base, size, numPages);
// We failed to get a blink page aligned chunk of
// memory. Unmap the chunk that we got and fall back to
// overallocating and selecting an aligned sub part of what
// we allocate.
int error = munmap(base, size);
RELEASE_ASSERT(!error);
size_t allocationSize = size + blinkPageSize;
base = static_cast<Address>(mmap(alignedRandomAddress, allocationSize, PROT_NONE, MAP_ANON | MAP_PRIVATE, -1, 0));
RELEASE_ASSERT(base != MAP_FAILED);
Address end = base + allocationSize;
Address alignedBase = roundToBlinkPageBoundary(base);
Address regionEnd = alignedBase + size;
// If the allocated memory was not blink page aligned release
// the memory before the aligned address.
if (alignedBase != base)
MemoryRegion(base, alignedBase - base).release();
// Free the additional memory at the end of the page if any.
if (regionEnd < end)
MemoryRegion(regionEnd, end - regionEnd).release();
return new PageMemoryRegion(alignedBase, size, numPages);
#else
Address base = static_cast<Address>(VirtualAlloc(alignedRandomAddress, size, MEM_RESERVE, PAGE_NOACCESS));
if (base) {
ASSERT(base == alignedRandomAddress);
return new PageMemoryRegion(base, size, numPages);
}
// We failed to get the random aligned address that we asked
// for. Fall back to overallocating. On Windows it is
// impossible to partially release a region of memory
// allocated by VirtualAlloc. To avoid wasting virtual address
// space we attempt to release a large region of memory
// returned as a whole and then allocate an aligned region
// inside this larger region.
size_t allocationSize = size + blinkPageSize;
for (int attempt = 0; attempt < 3; attempt++) {
base = static_cast<Address>(VirtualAlloc(0, allocationSize, MEM_RESERVE, PAGE_NOACCESS));
RELEASE_ASSERT(base);
VirtualFree(base, 0, MEM_RELEASE);
Address alignedBase = roundToBlinkPageBoundary(base);
base = static_cast<Address>(VirtualAlloc(alignedBase, size, MEM_RESERVE, PAGE_NOACCESS));
if (base) {
ASSERT(base == alignedBase);
return new PageMemoryRegion(alignedBase, size, numPages);
}
}
// We failed to avoid wasting virtual address space after
// several attempts.
base = static_cast<Address>(VirtualAlloc(0, allocationSize, MEM_RESERVE, PAGE_NOACCESS));
RELEASE_ASSERT(base);
// FIXME: If base is by accident blink page size aligned
// here then we can create two pages out of reserved
// space. Do this.
Address alignedBase = roundToBlinkPageBoundary(base);
return new PageMemoryRegion(alignedBase, size, numPages);
#endif
}
private:
PageMemoryRegion(Address base, size_t size, unsigned numPages)
: MemoryRegion(base, size)
, m_numPages(numPages)
{
}
unsigned m_numPages;
};
// Representation of the memory used for a Blink heap page.
//
// The representation keeps track of two memory regions:
//
// 1. The virtual memory reserved from the system in order to be able
// to free all the virtual memory reserved. Multiple PageMemory
// instances can share the same reserved memory region and
// therefore notify the reserved memory region on destruction so
// that the system memory can be given back when all PageMemory
// instances for that memory are gone.
//
// 2. The writable memory (a sub-region of the reserved virtual
// memory region) that is used for the actual heap page payload.
//
// Guard pages are created before and after the writable memory.
class PageMemory {
public:
~PageMemory()
{
__lsan_unregister_root_region(m_writable.base(), m_writable.size());
m_reserved->pageRemoved();
}
bool commit() WARN_UNUSED_RETURN { return m_writable.commit(); }
void decommit() { m_writable.decommit(); }
Address writableStart() { return m_writable.base(); }
static PageMemory* setupPageMemoryInRegion(PageMemoryRegion* region, size_t pageOffset, size_t payloadSize)
{
// Setup the payload one OS page into the page memory. The
// first os page is the guard page.
Address payloadAddress = region->base() + pageOffset + osPageSize();
return new PageMemory(region, MemoryRegion(payloadAddress, payloadSize));
}
// Allocate a virtual address space for one blink page with the
// following layout:
//
// [ guard os page | ... payload ... | guard os page ]
// ^---{ aligned to blink page size }
//
static PageMemory* allocate(size_t payloadSize)
{
ASSERT(payloadSize > 0);
// Virtual memory allocation routines operate in OS page sizes.
// Round up the requested size to nearest os page size.
payloadSize = roundToOsPageSize(payloadSize);
// Overallocate by 2 times OS page size to have space for a
// guard page at the beginning and end of blink heap page.
size_t allocationSize = payloadSize + 2 * osPageSize();
PageMemoryRegion* pageMemoryRegion = PageMemoryRegion::allocate(allocationSize, 1);
PageMemory* storage = setupPageMemoryInRegion(pageMemoryRegion, 0, payloadSize);
RELEASE_ASSERT(storage->commit());
return storage;
}
private:
PageMemory(PageMemoryRegion* reserved, const MemoryRegion& writable)
: m_reserved(reserved)
, m_writable(writable)
{
ASSERT(reserved->contains(writable));
// Register the writable area of the memory as part of the LSan root set.
// Only the writable area is mapped and can contain C++ objects. Those
// C++ objects can contain pointers to objects outside of the heap and
// should therefore be part of the LSan root set.
__lsan_register_root_region(m_writable.base(), m_writable.size());
}
PageMemoryRegion* m_reserved;
MemoryRegion m_writable;
};
class GCScope {
public:
explicit GCScope(ThreadState::StackState stackState)
: m_state(ThreadState::current())
, m_safePointScope(stackState)
, m_parkedAllThreads(false)
{
TRACE_EVENT0("blink_gc", "Heap::GCScope");
const char* samplingState = TRACE_EVENT_GET_SAMPLING_STATE();
if (m_state->isMainThread())
TRACE_EVENT_SET_SAMPLING_STATE("blink_gc", "BlinkGCWaiting");
m_state->checkThread();
// FIXME: in an unlikely coincidence that two threads decide
// to collect garbage at the same time, avoid doing two GCs in
// a row.
RELEASE_ASSERT(!m_state->isInGC());
RELEASE_ASSERT(!m_state->isSweepInProgress());
if (LIKELY(ThreadState::stopThreads())) {
m_parkedAllThreads = true;
m_state->enterGC();
}
if (m_state->isMainThread())
TRACE_EVENT_SET_NONCONST_SAMPLING_STATE(samplingState);
}
bool allThreadsParked() { return m_parkedAllThreads; }
~GCScope()
{
// Only cleanup if we parked all threads in which case the GC happened
// and we need to resume the other threads.
if (LIKELY(m_parkedAllThreads)) {
m_state->leaveGC();
ASSERT(!m_state->isInGC());
ThreadState::resumeThreads();
}
}
private:
ThreadState* m_state;
ThreadState::SafePointScope m_safePointScope;
bool m_parkedAllThreads; // False if we fail to park all threads
};
NO_SANITIZE_ADDRESS
bool HeapObjectHeader::isMarked() const
{
checkHeader();
unsigned size = acquireLoad(&m_size);
return size & markBitMask;
}
NO_SANITIZE_ADDRESS
void HeapObjectHeader::unmark()
{
checkHeader();
m_size &= ~markBitMask;
}
NO_SANITIZE_ADDRESS
bool HeapObjectHeader::hasDeadMark() const
{
checkHeader();
return m_size & deadBitMask;
}
NO_SANITIZE_ADDRESS
void HeapObjectHeader::clearDeadMark()
{
checkHeader();
m_size &= ~deadBitMask;
}
NO_SANITIZE_ADDRESS
void HeapObjectHeader::setDeadMark()
{
ASSERT(!isMarked());
checkHeader();
m_size |= deadBitMask;
}
#if ENABLE(ASSERT)
NO_SANITIZE_ADDRESS
void HeapObjectHeader::zapMagic()
{
m_magic = zappedMagic;
}
#endif
HeapObjectHeader* HeapObjectHeader::fromPayload(const void* payload)
{
Address addr = reinterpret_cast<Address>(const_cast<void*>(payload));
HeapObjectHeader* header =
reinterpret_cast<HeapObjectHeader*>(addr - objectHeaderSize);
return header;
}
void HeapObjectHeader::finalize(const GCInfo* gcInfo, Address object, size_t objectSize)
{
ASSERT(gcInfo);
if (gcInfo->hasFinalizer()) {
gcInfo->m_finalize(object);
}
#if ENABLE(ASSERT) || defined(LEAK_SANITIZER) || defined(ADDRESS_SANITIZER)
// In Debug builds, memory is zapped when it's freed, and the zapped memory is
// zeroed out when the memory is reused. Memory is also zapped when using Leak
// Sanitizer because the heap is used as a root region for LSan and therefore
// pointers in unreachable memory could hide leaks.
for (size_t i = 0; i < objectSize; i++)
object[i] = finalizedZapValue;
// Zap the primary vTable entry (secondary vTable entries are not zapped).
*(reinterpret_cast<uintptr_t*>(object)) = zappedVTable;
#endif
// In Release builds, the entire object is zeroed out when it is added to the free list.
// This happens right after sweeping the page and before the thread commences execution.
}
NO_SANITIZE_ADDRESS
void FinalizedHeapObjectHeader::finalize()
{
HeapObjectHeader::finalize(m_gcInfo, payload(), payloadSize());
}
template<typename Header>
void LargeHeapObject<Header>::unmark()
{
return heapObjectHeader()->unmark();
}
template<typename Header>
bool LargeHeapObject<Header>::isMarked()
{
return heapObjectHeader()->isMarked();
}
template<typename Header>
void LargeHeapObject<Header>::setDeadMark()
{
heapObjectHeader()->setDeadMark();
}
template<typename Header>
void LargeHeapObject<Header>::checkAndMarkPointer(Visitor* visitor, Address address)
{
ASSERT(contains(address));
if (!objectContains(address) || heapObjectHeader()->hasDeadMark())
return;
#if ENABLE(GC_PROFILE_MARKING)
visitor->setHostInfo(&address, "stack");
#endif
mark(visitor);
}
#if ENABLE(ASSERT)
static bool isUninitializedMemory(void* objectPointer, size_t objectSize)
{
// Scan through the object's fields and check that they are all zero.
Address* objectFields = reinterpret_cast<Address*>(objectPointer);
for (size_t i = 0; i < objectSize / sizeof(Address); ++i) {
if (objectFields[i] != 0)
return false;
}
return true;
}
#endif
template<>
void LargeHeapObject<FinalizedHeapObjectHeader>::mark(Visitor* visitor)
{
if (heapObjectHeader()->hasVTable() && !vTableInitialized(payload())) {
FinalizedHeapObjectHeader* header = heapObjectHeader();
visitor->markNoTracing(header);
ASSERT(isUninitializedMemory(header->payload(), header->payloadSize()));
} else {
visitor->mark(heapObjectHeader(), heapObjectHeader()->traceCallback());
}
}
template<>
void LargeHeapObject<HeapObjectHeader>::mark(Visitor* visitor)
{
ASSERT(gcInfo());
if (gcInfo()->hasVTable() && !vTableInitialized(payload())) {
HeapObjectHeader* header = heapObjectHeader();
visitor->markNoTracing(header);
ASSERT(isUninitializedMemory(header->payload(), header->payloadSize()));
} else {
visitor->mark(heapObjectHeader(), gcInfo()->m_trace);
}
}
template<>
void LargeHeapObject<FinalizedHeapObjectHeader>::finalize()
{
heapObjectHeader()->finalize();
}
template<>
void LargeHeapObject<HeapObjectHeader>::finalize()
{
ASSERT(gcInfo());
HeapObjectHeader::finalize(gcInfo(), payload(), payloadSize());
}
FinalizedHeapObjectHeader* FinalizedHeapObjectHeader::fromPayload(const void* payload)
{
Address addr = reinterpret_cast<Address>(const_cast<void*>(payload));
FinalizedHeapObjectHeader* header =
reinterpret_cast<FinalizedHeapObjectHeader*>(addr - finalizedHeaderSize);
return header;
}
template<typename Header>
ThreadHeap<Header>::ThreadHeap(ThreadState* state, int index)
: m_currentAllocationPoint(0)
, m_remainingAllocationSize(0)
, m_firstPage(0)
, m_firstLargeHeapObject(0)
, m_firstPageAllocatedDuringSweeping(0)
, m_lastPageAllocatedDuringSweeping(0)
, m_mergePoint(0)
, m_biggestFreeListIndex(0)
, m_threadState(state)
, m_index(index)
, m_numberOfNormalPages(0)
, m_promptlyFreedCount(0)
{
clearFreeLists();
}
template<typename Header>
ThreadHeap<Header>::~ThreadHeap()
{
ASSERT(!m_firstPage);
ASSERT(!m_firstLargeHeapObject);
}
template<typename Header>
void ThreadHeap<Header>::cleanupPages()
{
clearFreeLists();
flushHeapContainsCache();
// Add the ThreadHeap's pages to the orphanedPagePool.
for (HeapPage<Header>* page = m_firstPage; page; page = page->m_next)
Heap::orphanedPagePool()->addOrphanedPage(m_index, page);
m_firstPage = 0;
for (LargeHeapObject<Header>* largeObject = m_firstLargeHeapObject; largeObject; largeObject = largeObject->m_next)
Heap::orphanedPagePool()->addOrphanedPage(m_index, largeObject);
m_firstLargeHeapObject = 0;
}
template<typename Header>
Address ThreadHeap<Header>::outOfLineAllocate(size_t size, const GCInfo* gcInfo)
{
size_t allocationSize = allocationSizeFromSize(size);
if (threadState()->shouldGC()) {
if (threadState()->shouldForceConservativeGC())
Heap::collectGarbage(ThreadState::HeapPointersOnStack);
else
threadState()->setGCRequested();
}
ensureCurrentAllocation(allocationSize, gcInfo);
return allocate(size, gcInfo);
}
template<typename Header>
bool ThreadHeap<Header>::allocateFromFreeList(size_t minSize)
{
size_t bucketSize = 1 << m_biggestFreeListIndex;
int i = m_biggestFreeListIndex;
for (; i > 0; i--, bucketSize >>= 1) {
if (bucketSize < minSize)
break;
FreeListEntry* entry = m_freeLists[i];
if (entry) {
m_biggestFreeListIndex = i;
entry->unlink(&m_freeLists[i]);
setAllocationPoint(entry->address(), entry->size());
ASSERT(currentAllocationPoint() && remainingAllocationSize() >= minSize);
return true;
}
}
m_biggestFreeListIndex = i;
return false;
}
template<typename Header>
void ThreadHeap<Header>::ensureCurrentAllocation(size_t minSize, const GCInfo* gcInfo)
{
ASSERT(minSize >= allocationGranularity);
if (remainingAllocationSize() >= minSize)
return;
if (remainingAllocationSize() > 0)
addToFreeList(currentAllocationPoint(), remainingAllocationSize());
if (allocateFromFreeList(minSize))
return;
if (coalesce(minSize) && allocateFromFreeList(minSize))
return;
addPageToHeap(gcInfo);
bool success = allocateFromFreeList(minSize);
RELEASE_ASSERT(success);
}
template<typename Header>
BaseHeapPage* ThreadHeap<Header>::heapPageFromAddress(Address address)
{
for (HeapPage<Header>* page = m_firstPage; page; page = page->next()) {
if (page->contains(address))
return page;
}
for (HeapPage<Header>* page = m_firstPageAllocatedDuringSweeping; page; page = page->next()) {
if (page->contains(address))
return page;
}
for (LargeHeapObject<Header>* current = m_firstLargeHeapObject; current; current = current->next()) {
// Check that large pages are blinkPageSize aligned (modulo the
// osPageSize for the guard page).
ASSERT(reinterpret_cast<Address>(current) - osPageSize() == roundToBlinkPageStart(reinterpret_cast<Address>(current)));
if (current->contains(address))
return current;
}
return 0;
}
#if ENABLE(GC_PROFILE_MARKING)
template<typename Header>
const GCInfo* ThreadHeap<Header>::findGCInfoOfLargeHeapObject(Address address)
{
for (LargeHeapObject<Header>* current = m_firstLargeHeapObject; current; current = current->next()) {
if (current->contains(address))
return current->gcInfo();
}
return 0;
}
#endif
#if ENABLE(GC_PROFILE_HEAP)
#define GC_PROFILE_HEAP_PAGE_SNAPSHOT_THRESHOLD 0
template<typename Header>
void ThreadHeap<Header>::snapshot(TracedValue* json, ThreadState::SnapshotInfo* info)
{
size_t previousPageCount = info->pageCount;
json->beginArray("pages");
for (HeapPage<Header>* page = m_firstPage; page; page = page->next(), ++info->pageCount) {
// FIXME: To limit the size of the snapshot we only output "threshold" many page snapshots.
if (info->pageCount < GC_PROFILE_HEAP_PAGE_SNAPSHOT_THRESHOLD) {
json->beginArray();
json->pushInteger(reinterpret_cast<intptr_t>(page));
page->snapshot(json, info);
json->endArray();
} else {
page->snapshot(0, info);
}
}
json->endArray();
json->beginArray("largeObjects");
for (LargeHeapObject<Header>* current = m_firstLargeHeapObject; current; current = current->next()) {
json->beginDictionary();
current->snapshot(json, info);
json->endDictionary();
}
json->endArray();
json->setInteger("pageCount", info->pageCount - previousPageCount);
}
#endif
template<typename Header>
void ThreadHeap<Header>::addToFreeList(Address address, size_t size)
{
ASSERT(heapPageFromAddress(address));
ASSERT(heapPageFromAddress(address + size - 1));
ASSERT(size < blinkPagePayloadSize());
// The free list entries are only pointer aligned (but when we allocate
// from them we are 8 byte aligned due to the header size).
ASSERT(!((reinterpret_cast<uintptr_t>(address) + sizeof(Header)) & allocationMask));
ASSERT(!(size & allocationMask));
ASAN_POISON_MEMORY_REGION(address, size);
FreeListEntry* entry;
if (size < sizeof(*entry)) {
// Create a dummy header with only a size and freelist bit set.
ASSERT(size >= sizeof(BasicObjectHeader));
// Free list encode the size to mark the lost memory as freelist memory.
new (NotNull, address) BasicObjectHeader(BasicObjectHeader::freeListEncodedSize(size));
// This memory gets lost. Sweeping can reclaim it.
return;
}
entry = new (NotNull, address) FreeListEntry(size);
#if defined(ADDRESS_SANITIZER)
// For ASan we don't add the entry to the free lists until the asanDeferMemoryReuseCount
// reaches zero. However we always add entire pages to ensure that adding a new page will
// increase the allocation space.
if (HeapPage<Header>::payloadSize() != size && !entry->shouldAddToFreeList())
return;
#endif
int index = bucketIndexForSize(size);
entry->link(&m_freeLists[index]);
if (!m_lastFreeListEntries[index])
m_lastFreeListEntries[index] = entry;
if (index > m_biggestFreeListIndex)
m_biggestFreeListIndex = index;
}
template<typename Header>
void ThreadHeap<Header>::promptlyFreeObject(Header* header)
{
ASSERT(!m_threadState->isSweepInProgress());
header->checkHeader();
Address address = reinterpret_cast<Address>(header);
Address payload = header->payload();
size_t size = header->size();
size_t payloadSize = header->payloadSize();
BaseHeapPage* page = pageHeaderFromObject(address);
ASSERT(size > 0);
ASSERT(page == heapPageFromAddress(address));
{
ThreadState::NoSweepScope scope(m_threadState);
HeapObjectHeader::finalize(header->gcInfo(), payload, payloadSize);
#if !ENABLE(ASSERT) && !defined(LEAK_SANITIZER) && !defined(ADDRESS_SANITIZER)
memset(payload, 0, payloadSize);
#endif
header->markPromptlyFreed();
}
page->addToPromptlyFreedSize(size);
m_promptlyFreedCount++;
}
template<typename Header>
bool ThreadHeap<Header>::coalesce(size_t minSize)
{
if (m_threadState->isSweepInProgress())
return false;
if (m_promptlyFreedCount < 256)
return false;
// The smallest bucket able to satisfy an allocation request for minSize is
// the bucket where all free-list entries are guarantied to be larger than
// minSize. That bucket is one larger than the bucket minSize would go into.
size_t neededBucketIndex = bucketIndexForSize(minSize) + 1;
size_t neededFreeEntrySize = 1 << neededBucketIndex;
size_t neededPromptlyFreedSize = neededFreeEntrySize * 3;
size_t foundFreeEntrySize = 0;
// Bailout early on large requests because it is unlikely we will find a free-list entry.
if (neededPromptlyFreedSize >= blinkPageSize)
return false;
TRACE_EVENT_BEGIN2("blink_gc", "ThreadHeap::coalesce" , "requestedSize", (unsigned)minSize , "neededSize", (unsigned)neededFreeEntrySize);
// Search for a coalescing candidate.
ASSERT(!ownsNonEmptyAllocationArea());
size_t pageCount = 0;
HeapPage<Header>* page = m_firstPage;
while (page) {
// Only consider one of the first 'n' pages. A "younger" page is more likely to have freed backings.
if (++pageCount > numberOfPagesToConsiderForCoalescing) {
page = 0;
break;
}
// Only coalesce pages with "sufficient" promptly freed space.
if (page->promptlyFreedSize() >= neededPromptlyFreedSize) {
break;
}
page = page->next();
}
// If we found a likely candidate, fully coalesce all its promptly-freed entries.
if (page) {
page->clearObjectStartBitMap();
page->resetPromptlyFreedSize();
size_t freedCount = 0;
Address startOfGap = page->payload();
for (Address headerAddress = startOfGap; headerAddress < page->end(); ) {
BasicObjectHeader* basicHeader = reinterpret_cast<BasicObjectHeader*>(headerAddress);
ASSERT(basicHeader->size() > 0);
ASSERT(basicHeader->size() < blinkPagePayloadSize());
if (basicHeader->isPromptlyFreed()) {
stats().decreaseObjectSpace(reinterpret_cast<Header*>(basicHeader)->payloadSize());
size_t size = basicHeader->size();
ASSERT(size >= sizeof(Header));
#if !ENABLE(ASSERT) && !defined(LEAK_SANITIZER) && !defined(ADDRESS_SANITIZER)
memset(headerAddress, 0, sizeof(Header));
#endif
++freedCount;
headerAddress += size;
continue;
}
if (startOfGap != headerAddress) {
size_t size = headerAddress - startOfGap;
addToFreeList(startOfGap, size);
if (size > foundFreeEntrySize)
foundFreeEntrySize = size;
}
headerAddress += basicHeader->size();
startOfGap = headerAddress;
}
if (startOfGap != page->end()) {
size_t size = page->end() - startOfGap;
addToFreeList(startOfGap, size);
if (size > foundFreeEntrySize)
foundFreeEntrySize = size;
}
// Check before subtracting because freedCount might not be balanced with freed entries.
if (freedCount < m_promptlyFreedCount)
m_promptlyFreedCount -= freedCount;
else
m_promptlyFreedCount = 0;
}
TRACE_EVENT_END1("blink_gc", "ThreadHeap::coalesce", "foundFreeEntrySize", (unsigned)foundFreeEntrySize);
if (foundFreeEntrySize < neededFreeEntrySize) {
// If coalescing failed, reset the freed count to delay coalescing again.
m_promptlyFreedCount = 0;
return false;
}
return true;
}
template<typename Header>
Address ThreadHeap<Header>::allocateLargeObject(size_t size, const GCInfo* gcInfo)
{
// Caller already added space for object header and rounded up to allocation alignment
ASSERT(!(size & allocationMask));
size_t allocationSize = sizeof(LargeHeapObject<Header>) + size;
// Ensure that there is enough space for alignment. If the header
// is not a multiple of 8 bytes we will allocate an extra
// headerPadding<Header> bytes to ensure it 8 byte aligned.
allocationSize += headerPadding<Header>();
// If ASan is supported we add allocationGranularity bytes to the allocated space and
// poison that to detect overflows
#if defined(ADDRESS_SANITIZER)
allocationSize += allocationGranularity;
#endif
if (threadState()->shouldGC())
threadState()->setGCRequested();
Heap::flushHeapDoesNotContainCache();
PageMemory* pageMemory = PageMemory::allocate(allocationSize);
Address largeObjectAddress = pageMemory->writableStart();
Address headerAddress = largeObjectAddress + sizeof(LargeHeapObject<Header>) + headerPadding<Header>();
memset(headerAddress, 0, size);
Header* header = new (NotNull, headerAddress) Header(size, gcInfo);
Address result = headerAddress + sizeof(*header);
ASSERT(!(reinterpret_cast<uintptr_t>(result) & allocationMask));
LargeHeapObject<Header>* largeObject = new (largeObjectAddress) LargeHeapObject<Header>(pageMemory, gcInfo, threadState());
// Poison the object header and allocationGranularity bytes after the object
ASAN_POISON_MEMORY_REGION(header, sizeof(*header));
ASAN_POISON_MEMORY_REGION(largeObject->address() + largeObject->size(), allocationGranularity);
largeObject->link(&m_firstLargeHeapObject);
stats().increaseAllocatedSpace(largeObject->size());
stats().increaseObjectSpace(largeObject->payloadSize());
return result;
}
template<typename Header>
void ThreadHeap<Header>::freeLargeObject(LargeHeapObject<Header>* object, LargeHeapObject<Header>** previousNext)
{
flushHeapContainsCache();
object->unlink(previousNext);
object->finalize();
// Unpoison the object header and allocationGranularity bytes after the
// object before freeing.
ASAN_UNPOISON_MEMORY_REGION(object->heapObjectHeader(), sizeof(Header));
ASAN_UNPOISON_MEMORY_REGION(object->address() + object->size(), allocationGranularity);
if (object->terminating()) {
ASSERT(ThreadState::current()->isTerminating());
// The thread is shutting down so this object is being removed as part
// of a thread local GC. In that case the object could be traced in the
// next global GC either due to a dead object being traced via a
// conservative pointer or due to a programming error where an object
// in another thread heap keeps a dangling pointer to this object.
// To guard against this we put the large object memory in the
// orphanedPagePool to ensure it is still reachable. After the next global
// GC it can be released assuming no rogue/dangling pointers refer to
// it.
// NOTE: large objects are not moved to the free page pool as it is
// unlikely they can be reused due to their individual sizes.
Heap::orphanedPagePool()->addOrphanedPage(m_index, object);
} else {
ASSERT(!ThreadState::current()->isTerminating());
PageMemory* memory = object->storage();
object->~LargeHeapObject<Header>();
delete memory;
}
}
template<typename DataType>
PagePool<DataType>::PagePool()
{
for (int i = 0; i < NumberOfHeaps; ++i) {
m_pool[i] = 0;
}
}
FreePagePool::~FreePagePool()
{
for (int index = 0; index < NumberOfHeaps; ++index) {
while (PoolEntry* entry = m_pool[index]) {
m_pool[index] = entry->next;
PageMemory* memory = entry->data;
ASSERT(memory);
delete memory;
delete entry;
}
}
}
void FreePagePool::addFreePage(int index, PageMemory* memory)
{
// When adding a page to the pool we decommit it to ensure it is unused
// while in the pool. This also allows the physical memory, backing the
// page, to be given back to the OS.
memory->decommit();
MutexLocker locker(m_mutex[index]);
PoolEntry* entry = new PoolEntry(memory, m_pool[index]);
m_pool[index] = entry;
}
PageMemory* FreePagePool::takeFreePage(int index)
{
MutexLocker locker(m_mutex[index]);
while (PoolEntry* entry = m_pool[index]) {
m_pool[index] = entry->next;
PageMemory* memory = entry->data;
ASSERT(memory);
delete entry;
if (memory->commit())
return memory;
// We got some memory, but failed to commit it, try again.
delete memory;
}
return 0;
}
OrphanedPagePool::~OrphanedPagePool()
{
for (int index = 0; index < NumberOfHeaps; ++index) {
while (PoolEntry* entry = m_pool[index]) {
m_pool[index] = entry->next;
BaseHeapPage* page = entry->data;
delete entry;
PageMemory* memory = page->storage();
ASSERT(memory);
page->~BaseHeapPage();
delete memory;
}
}
}
void OrphanedPagePool::addOrphanedPage(int index, BaseHeapPage* page)
{
page->markOrphaned();
PoolEntry* entry = new PoolEntry(page, m_pool[index]);
m_pool[index] = entry;
}
NO_SANITIZE_ADDRESS
void OrphanedPagePool::decommitOrphanedPages()
{
#if ENABLE(ASSERT)
// No locking needed as all threads are at safepoints at this point in time.
ThreadState::AttachedThreadStateSet& threads = ThreadState::attachedThreads();
for (ThreadState::AttachedThreadStateSet::iterator it = threads.begin(), end = threads.end(); it != end; ++it)
ASSERT((*it)->isAtSafePoint());
#endif
for (int index = 0; index < NumberOfHeaps; ++index) {
PoolEntry* entry = m_pool[index];
PoolEntry** prevNext = &m_pool[index];
while (entry) {
BaseHeapPage* page = entry->data;
if (page->tracedAfterOrphaned()) {
// If the orphaned page was traced in the last GC it is not
// decommited. We only decommit a page, ie. put it in the
// memory pool, when the page has no objects pointing to it.
// We remark the page as orphaned to clear the tracedAfterOrphaned
// flag and any object trace bits that were set during tracing.
page->markOrphaned();
prevNext = &entry->next;
entry = entry->next;
continue;
}
// Page was not traced. Check if we should reuse the memory or just
// free it. Large object memory is not reused, but freed, normal
// blink heap pages are reused.
// NOTE: We call the destructor before freeing or adding to the
// free page pool.
PageMemory* memory = page->storage();
if (page->isLargeObject()) {
page->~BaseHeapPage();
delete memory;
} else {
page->~BaseHeapPage();
// Clear out the page's memory before adding it to the free page
// pool to ensure it is zero filled when being reused.
clearMemory(memory);
Heap::freePagePool()->addFreePage(index, memory);
}
PoolEntry* deadEntry = entry;
entry = entry->next;
*prevNext = entry;
delete deadEntry;
}
}
}
NO_SANITIZE_ADDRESS
void OrphanedPagePool::clearMemory(PageMemory* memory)
{
#if defined(ADDRESS_SANITIZER)
// Don't use memset when running with ASan since this needs to zap
// poisoned memory as well and the NO_SANITIZE_ADDRESS annotation
// only works for code in this method and not for calls to memset.
Address base = memory->writableStart();
for (Address current = base; current < base + blinkPagePayloadSize(); ++current)
*current = 0;
#else
memset(memory->writableStart(), 0, blinkPagePayloadSize());
#endif
}
#if ENABLE(ASSERT)
bool OrphanedPagePool::contains(void* object)
{
for (int index = 0; index < NumberOfHeaps; ++index) {
for (PoolEntry* entry = m_pool[index]; entry; entry = entry->next) {
BaseHeapPage* page = entry->data;
if (page->contains(reinterpret_cast<Address>(object)))
return true;
}
}
return false;
}
#endif
template<>
void ThreadHeap<FinalizedHeapObjectHeader>::addPageToHeap(const GCInfo* gcInfo)
{
// When adding a page to the ThreadHeap using FinalizedHeapObjectHeaders the GCInfo on
// the heap should be unused (ie. 0).
allocatePage(0);
}
template<>
void ThreadHeap<HeapObjectHeader>::addPageToHeap(const GCInfo* gcInfo)
{
// When adding a page to the ThreadHeap using HeapObjectHeaders store the GCInfo on the heap
// since it is the same for all objects
ASSERT(gcInfo);
allocatePage(gcInfo);
}
template <typename Header>
void ThreadHeap<Header>::removePageFromHeap(HeapPage<Header>* page)
{
MutexLocker locker(m_threadState->sweepMutex());
flushHeapContainsCache();
if (page->terminating()) {
// The thread is shutting down so this page is being removed as part
// of a thread local GC. In that case the page could be accessed in the
// next global GC either due to a dead object being traced via a
// conservative pointer or due to a programming error where an object
// in another thread heap keeps a dangling pointer to this object.
// To guard against this we put the page in the orphanedPagePool to
// ensure it is still reachable. After the next global GC it can be
// decommitted and moved to the page pool assuming no rogue/dangling
// pointers refer to it.
Heap::orphanedPagePool()->addOrphanedPage(m_index, page);
} else {
PageMemory* memory = page->storage();
page->~HeapPage<Header>();
Heap::freePagePool()->addFreePage(m_index, memory);
}
}
template<typename Header>
void ThreadHeap<Header>::allocatePage(const GCInfo* gcInfo)
{
Heap::flushHeapDoesNotContainCache();
PageMemory* pageMemory = Heap::freePagePool()->takeFreePage(m_index);
// We continue allocating page memory until we succeed in getting one.
// Since the FreePagePool is global other threads could use all the
// newly allocated page memory before this thread calls takeFreePage.
while (!pageMemory) {
// Allocate a memory region for blinkPagesPerRegion pages that
// will each have the following layout.
//
// [ guard os page | ... payload ... | guard os page ]
// ^---{ aligned to blink page size }
PageMemoryRegion* region = PageMemoryRegion::allocate(blinkPageSize * blinkPagesPerRegion, blinkPagesPerRegion);
// Setup the PageMemory object for each of the pages in the
// region.
size_t offset = 0;
for (size_t i = 0; i < blinkPagesPerRegion; i++) {
Heap::freePagePool()->addFreePage(m_index, PageMemory::setupPageMemoryInRegion(region, offset, blinkPagePayloadSize()));
offset += blinkPageSize;
}
pageMemory = Heap::freePagePool()->takeFreePage(m_index);
}
HeapPage<Header>* page = new (pageMemory->writableStart()) HeapPage<Header>(pageMemory, this, gcInfo);
// Use a separate list for pages allocated during sweeping to make
// sure that we do not accidentally sweep objects that have been
// allocated during sweeping.
if (m_threadState->isSweepInProgress()) {
if (!m_lastPageAllocatedDuringSweeping)
m_lastPageAllocatedDuringSweeping = page;
page->link(&m_firstPageAllocatedDuringSweeping);
} else {
page->link(&m_firstPage);
}
++m_numberOfNormalPages;
addToFreeList(page->payload(), HeapPage<Header>::payloadSize());
}
#if ENABLE(ASSERT)
template<typename Header>
bool ThreadHeap<Header>::pagesToBeSweptContains(Address address)
{
for (HeapPage<Header>* page = m_firstPage; page; page = page->next()) {
if (page->contains(address))
return true;
}
return false;
}
template<typename Header>
bool ThreadHeap<Header>::pagesAllocatedDuringSweepingContains(Address address)
{
for (HeapPage<Header>* page = m_firstPageAllocatedDuringSweeping; page; page = page->next()) {
if (page->contains(address))
return true;
}
return false;
}
template<typename Header>
void ThreadHeap<Header>::getScannedStats(HeapStats& scannedStats)
{
ASSERT(!m_firstPageAllocatedDuringSweeping);
for (HeapPage<Header>* page = m_firstPage; page; page = page->next())
page->getStats(scannedStats);
for (LargeHeapObject<Header>* current = m_firstLargeHeapObject; current; current = current->next())
current->getStats(scannedStats);
}
#endif
template<typename Header>
void ThreadHeap<Header>::sweepNormalPages(HeapStats* stats)
{
HeapPage<Header>* page = m_firstPage;
HeapPage<Header>** previousNext = &m_firstPage;
HeapPage<Header>* previous = 0;
while (page) {
page->resetPromptlyFreedSize();
if (page->isEmpty()) {
HeapPage<Header>* unused = page;
if (unused == m_mergePoint)
m_mergePoint = previous;
page = page->next();
HeapPage<Header>::unlink(this, unused, previousNext);
--m_numberOfNormalPages;
} else {
page->sweep(stats, this);
previousNext = &page->m_next;
previous = page;
page = page->next();
}
}
}
template<typename Header>
void ThreadHeap<Header>::sweepLargePages(HeapStats* stats)
{
LargeHeapObject<Header>** previousNext = &m_firstLargeHeapObject;
for (LargeHeapObject<Header>* current = m_firstLargeHeapObject; current;) {
if (current->isMarked()) {
stats->increaseAllocatedSpace(current->size());
stats->increaseObjectSpace(current->payloadSize());
current->unmark();
previousNext = &current->m_next;
current = current->next();
} else {
LargeHeapObject<Header>* next = current->next();
freeLargeObject(current, previousNext);
current = next;
}
}
}
// STRICT_ASAN_FINALIZATION_CHECKING turns on poisoning of all objects during
// sweeping to catch cases where dead objects touch each other. This is not
// turned on by default because it also triggers for cases that are safe.
// Examples of such safe cases are context life cycle observers and timers
// embedded in garbage collected objects.
#define STRICT_ASAN_FINALIZATION_CHECKING 0
template<typename Header>
void ThreadHeap<Header>::sweep(HeapStats* stats)
{
ASSERT(isConsistentForSweeping());
#if defined(ADDRESS_SANITIZER) && STRICT_ASAN_FINALIZATION_CHECKING
// When using ASan do a pre-sweep where all unmarked objects are
// poisoned before calling their finalizer methods. This can catch
// the case where the finalizer of an object tries to modify
// another object as part of finalization.
for (HeapPage<Header>* page = m_firstPage; page; page = page->next())
page->poisonUnmarkedObjects();
#endif
sweepNormalPages(stats);
sweepLargePages(stats);
}
template<typename Header>
void ThreadHeap<Header>::postSweepProcessing()
{
// If pages have been allocated during sweeping, link them into
// the list of pages.
if (m_firstPageAllocatedDuringSweeping) {
m_lastPageAllocatedDuringSweeping->m_next = m_firstPage;
m_firstPage = m_firstPageAllocatedDuringSweeping;
m_lastPageAllocatedDuringSweeping = 0;
m_firstPageAllocatedDuringSweeping = 0;
}
}
#if ENABLE(ASSERT)
template<typename Header>
bool ThreadHeap<Header>::isConsistentForSweeping()
{
// A thread heap is consistent for sweeping if none of the pages to
// be swept contain a freelist block or the current allocation
// point.
for (size_t i = 0; i < blinkPageSizeLog2; i++) {
for (FreeListEntry* freeListEntry = m_freeLists[i]; freeListEntry; freeListEntry = freeListEntry->next()) {
if (pagesToBeSweptContains(freeListEntry->address())) {
return false;
}
ASSERT(pagesAllocatedDuringSweepingContains(freeListEntry->address()));
}
}
if (ownsNonEmptyAllocationArea()) {
ASSERT(pagesToBeSweptContains(currentAllocationPoint())
|| pagesAllocatedDuringSweepingContains(currentAllocationPoint()));
return !pagesToBeSweptContains(currentAllocationPoint());
}
return true;
}
#endif
template<typename Header>
void ThreadHeap<Header>::makeConsistentForSweeping()
{
if (ownsNonEmptyAllocationArea())
addToFreeList(currentAllocationPoint(), remainingAllocationSize());
setAllocationPoint(0, 0);
clearFreeLists();
}
template<typename Header>
void ThreadHeap<Header>::clearLiveAndMarkDead()
{
ASSERT(isConsistentForSweeping());
for (HeapPage<Header>* page = m_firstPage; page; page = page->next())
page->clearLiveAndMarkDead();
for (LargeHeapObject<Header>* current = m_firstLargeHeapObject; current; current = current->next()) {
if (current->isMarked())
current->unmark();
else
current->setDeadMark();
}
}
template<typename Header>
void ThreadHeap<Header>::clearFreeLists()
{
m_promptlyFreedCount = 0;
for (size_t i = 0; i < blinkPageSizeLog2; i++) {
m_freeLists[i] = 0;
m_lastFreeListEntries[i] = 0;
}
}
int BaseHeap::bucketIndexForSize(size_t size)
{
ASSERT(size > 0);
int index = -1;
while (size) {
size >>= 1;
index++;
}
return index;
}
template<typename Header>
HeapPage<Header>::HeapPage(PageMemory* storage, ThreadHeap<Header>* heap, const GCInfo* gcInfo)
: BaseHeapPage(storage, gcInfo, heap->threadState())
, m_next(0)
{
COMPILE_ASSERT(!(sizeof(HeapPage<Header>) & allocationMask), page_header_incorrectly_aligned);
m_objectStartBitMapComputed = false;
ASSERT(isPageHeaderAddress(reinterpret_cast<Address>(this)));
heap->stats().increaseAllocatedSpace(blinkPageSize);
}
template<typename Header>
void HeapPage<Header>::link(HeapPage** prevNext)
{
m_next = *prevNext;
*prevNext = this;
}
template<typename Header>
void HeapPage<Header>::unlink(ThreadHeap<Header>* heap, HeapPage* unused, HeapPage** prevNext)
{
*prevNext = unused->m_next;
heap->removePageFromHeap(unused);
}
template<typename Header>
void HeapPage<Header>::getStats(HeapStats& stats)
{
stats.increaseAllocatedSpace(blinkPageSize);
Address headerAddress = payload();
ASSERT(headerAddress != end());
do {
Header* header = reinterpret_cast<Header*>(headerAddress);
if (!header->isFree())
stats.increaseObjectSpace(header->payloadSize());
ASSERT(header->size() < blinkPagePayloadSize());
headerAddress += header->size();
ASSERT(headerAddress <= end());
} while (headerAddress < end());
}
template<typename Header>
bool HeapPage<Header>::isEmpty()
{
BasicObjectHeader* header = reinterpret_cast<BasicObjectHeader*>(payload());
return header->isFree() && (header->size() == payloadSize());
}
template<typename Header>
void HeapPage<Header>::sweep(HeapStats* stats, ThreadHeap<Header>* heap)
{
clearObjectStartBitMap();
stats->increaseAllocatedSpace(blinkPageSize);
Address startOfGap = payload();
for (Address headerAddress = startOfGap; headerAddress < end(); ) {
BasicObjectHeader* basicHeader = reinterpret_cast<BasicObjectHeader*>(headerAddress);
ASSERT(basicHeader->size() > 0);
ASSERT(basicHeader->size() < blinkPagePayloadSize());
if (basicHeader->isFree()) {
size_t size = basicHeader->size();
#if !ENABLE(ASSERT) && !defined(LEAK_SANITIZER) && !defined(ADDRESS_SANITIZER)
// Zero the memory in the free list header to maintain the
// invariant that memory on the free list is zero filled.
// The rest of the memory is already on the free list and is
// therefore already zero filled.
if (size < sizeof(FreeListEntry))
memset(headerAddress, 0, size);
else
memset(headerAddress, 0, sizeof(FreeListEntry));
#endif
headerAddress += size;
continue;
}
// At this point we know this is a valid object of type Header
Header* header = static_cast<Header*>(basicHeader);
if (!header->isMarked()) {
// For ASan we unpoison the specific object when calling the finalizer and
// poison it again when done to allow the object's own finalizer to operate
// on the object, but not have other finalizers be allowed to access it.
ASAN_UNPOISON_MEMORY_REGION(header->payload(), header->payloadSize());
finalize(header);
size_t size = header->size();
#if !ENABLE(ASSERT) && !defined(LEAK_SANITIZER) && !defined(ADDRESS_SANITIZER)
// This memory will be added to the freelist. Maintain the invariant
// that memory on the freelist is zero filled.
memset(headerAddress, 0, size);
#endif
ASAN_POISON_MEMORY_REGION(header->payload(), header->payloadSize());
headerAddress += size;
continue;
}
if (startOfGap != headerAddress)
heap->addToFreeList(startOfGap, headerAddress - startOfGap);
header->unmark();
headerAddress += header->size();
stats->increaseObjectSpace(header->payloadSize());
startOfGap = headerAddress;
}
if (startOfGap != end())
heap->addToFreeList(startOfGap, end() - startOfGap);
}
template<typename Header>
void HeapPage<Header>::clearLiveAndMarkDead()
{
for (Address headerAddress = payload(); headerAddress < end();) {
Header* header = reinterpret_cast<Header*>(headerAddress);
ASSERT(header->size() < blinkPagePayloadSize());
// Check if a free list entry first since we cannot call
// isMarked on a free list entry.
if (header->isFree()) {
headerAddress += header->size();
continue;
}
if (header->isMarked())
header->unmark();
else
header->setDeadMark();
headerAddress += header->size();
}
}
template<typename Header>
void HeapPage<Header>::populateObjectStartBitMap()
{
memset(&m_objectStartBitMap, 0, objectStartBitMapSize);
Address start = payload();
for (Address headerAddress = start; headerAddress < end();) {
Header* header = reinterpret_cast<Header*>(headerAddress);
size_t objectOffset = headerAddress - start;
ASSERT(!(objectOffset & allocationMask));
size_t objectStartNumber = objectOffset / allocationGranularity;
size_t mapIndex = objectStartNumber / 8;
ASSERT(mapIndex < objectStartBitMapSize);
m_objectStartBitMap[mapIndex] |= (1 << (objectStartNumber & 7));
headerAddress += header->size();
ASSERT(headerAddress <= end());
}
m_objectStartBitMapComputed = true;
}
template<typename Header>
void HeapPage<Header>::clearObjectStartBitMap()
{
m_objectStartBitMapComputed = false;
}
static int numberOfLeadingZeroes(uint8_t byte)
{
if (!byte)
return 8;
int result = 0;
if (byte <= 0x0F) {
result += 4;
byte = byte << 4;
}
if (byte <= 0x3F) {
result += 2;
byte = byte << 2;
}
if (byte <= 0x7F)
result++;
return result;
}
template<typename Header>
Header* HeapPage<Header>::findHeaderFromAddress(Address address)
{
if (address < payload())
return 0;
if (!isObjectStartBitMapComputed())
populateObjectStartBitMap();
size_t objectOffset = address - payload();
size_t objectStartNumber = objectOffset / allocationGranularity;
size_t mapIndex = objectStartNumber / 8;
ASSERT(mapIndex < objectStartBitMapSize);
size_t bit = objectStartNumber & 7;
uint8_t byte = m_objectStartBitMap[mapIndex] & ((1 << (bit + 1)) - 1);
while (!byte) {
ASSERT(mapIndex > 0);
byte = m_objectStartBitMap[--mapIndex];
}
int leadingZeroes = numberOfLeadingZeroes(byte);
objectStartNumber = (mapIndex * 8) + 7 - leadingZeroes;
objectOffset = objectStartNumber * allocationGranularity;
Address objectAddress = objectOffset + payload();
Header* header = reinterpret_cast<Header*>(objectAddress);
if (header->isFree())
return 0;
return header;
}
template<typename Header>
void HeapPage<Header>::checkAndMarkPointer(Visitor* visitor, Address address)
{
ASSERT(contains(address));
Header* header = findHeaderFromAddress(address);
if (!header || header->hasDeadMark())
return;
#if ENABLE(GC_PROFILE_MARKING)
visitor->setHostInfo(&address, "stack");
#endif
if (hasVTable(header) && !vTableInitialized(header->payload())) {
visitor->markNoTracing(header);
ASSERT(isUninitializedMemory(header->payload(), header->payloadSize()));
} else {
visitor->mark(header, traceCallback(header));
}
}
#if ENABLE(GC_PROFILE_MARKING)
template<typename Header>
const GCInfo* HeapPage<Header>::findGCInfo(Address address)
{
if (address < payload())
return 0;
if (gcInfo()) // for non FinalizedObjectHeader
return gcInfo();
Header* header = findHeaderFromAddress(address);
if (!header)
return 0;
return header->gcInfo();
}
#endif
#if ENABLE(GC_PROFILE_HEAP)
template<typename Header>
void HeapPage<Header>::snapshot(TracedValue* json, ThreadState::SnapshotInfo* info)
{
Header* header = 0;
for (Address addr = payload(); addr < end(); addr += header->size()) {
header = reinterpret_cast<Header*>(addr);
if (json)
json->pushInteger(header->encodedSize());
if (header->isFree()) {
info->freeSize += header->size();
continue;
}
const GCInfo* gcinfo = header->gcInfo() ? header->gcInfo() : gcInfo();
size_t tag = info->getClassTag(gcinfo);
size_t age = header->age();
if (json)
json->pushInteger(tag);
if (header->isMarked()) {
info->liveCount[tag] += 1;
info->liveSize[tag] += header->size();
// Count objects that are live when promoted to the final generation.
if (age == maxHeapObjectAge - 1)
info->generations[tag][maxHeapObjectAge] += 1;
header->incAge();
} else {
info->deadCount[tag] += 1;
info->deadSize[tag] += header->size();
// Count objects that are dead before the final generation.
if (age < maxHeapObjectAge)
info->generations[tag][age] += 1;
}
}
}
#endif
#if defined(ADDRESS_SANITIZER)
template<typename Header>
void HeapPage<Header>::poisonUnmarkedObjects()
{
for (Address headerAddress = payload(); headerAddress < end(); ) {
Header* header = reinterpret_cast<Header*>(headerAddress);
ASSERT(header->size() < blinkPagePayloadSize());
if (!header->isFree() && !header->isMarked())
ASAN_POISON_MEMORY_REGION(header->payload(), header->payloadSize());
headerAddress += header->size();
}
}
#endif
template<>
inline void HeapPage<FinalizedHeapObjectHeader>::finalize(FinalizedHeapObjectHeader* header)
{
header->finalize();
}
template<>
inline void HeapPage<HeapObjectHeader>::finalize(HeapObjectHeader* header)
{
ASSERT(gcInfo());
HeapObjectHeader::finalize(gcInfo(), header->payload(), header->payloadSize());
}
template<>
inline TraceCallback HeapPage<HeapObjectHeader>::traceCallback(HeapObjectHeader* header)
{
ASSERT(gcInfo());
return gcInfo()->m_trace;
}
template<>
inline TraceCallback HeapPage<FinalizedHeapObjectHeader>::traceCallback(FinalizedHeapObjectHeader* header)
{
return header->traceCallback();
}
template<>
inline bool HeapPage<HeapObjectHeader>::hasVTable(HeapObjectHeader* header)
{
ASSERT(gcInfo());
return gcInfo()->hasVTable();
}
template<>
inline bool HeapPage<FinalizedHeapObjectHeader>::hasVTable(FinalizedHeapObjectHeader* header)
{
return header->hasVTable();
}
template<typename Header>
void LargeHeapObject<Header>::getStats(HeapStats& stats)
{
stats.increaseAllocatedSpace(size());
stats.increaseObjectSpace(payloadSize());
}
#if ENABLE(GC_PROFILE_HEAP)
template<typename Header>
void LargeHeapObject<Header>::snapshot(TracedValue* json, ThreadState::SnapshotInfo* info)
{
Header* header = heapObjectHeader();
size_t tag = info->getClassTag(header->gcInfo());
size_t age = header->age();
if (isMarked()) {
info->liveCount[tag] += 1;
info->liveSize[tag] += header->size();
// Count objects that are live when promoted to the final generation.
if (age == maxHeapObjectAge - 1)
info->generations[tag][maxHeapObjectAge] += 1;
header->incAge();
} else {
info->deadCount[tag] += 1;
info->deadSize[tag] += header->size();
// Count objects that are dead before the final generation.
if (age < maxHeapObjectAge)
info->generations[tag][age] += 1;
}
if (json) {
json->setInteger("class", tag);
json->setInteger("size", header->size());
json->setInteger("isMarked", isMarked());
}
}
#endif
template<typename Entry>
void HeapExtentCache<Entry>::flush()
{
if (m_hasEntries) {
for (int i = 0; i < numberOfEntries; i++)
m_entries[i] = Entry();
m_hasEntries = false;
}
}
template<typename Entry>
size_t HeapExtentCache<Entry>::hash(Address address)
{
size_t value = (reinterpret_cast<size_t>(address) >> blinkPageSizeLog2);
value ^= value >> numberOfEntriesLog2;
value ^= value >> (numberOfEntriesLog2 * 2);
value &= numberOfEntries - 1;
return value & ~1; // Returns only even number.
}
template<typename Entry>
typename Entry::LookupResult HeapExtentCache<Entry>::lookup(Address address)
{
size_t index = hash(address);
ASSERT(!(index & 1));
Address cachePage = roundToBlinkPageStart(address);
if (m_entries[index].address() == cachePage)
return m_entries[index].result();
if (m_entries[index + 1].address() == cachePage)
return m_entries[index + 1].result();
return 0;
}
template<typename Entry>
void HeapExtentCache<Entry>::addEntry(Address address, typename Entry::LookupResult entry)
{
m_hasEntries = true;
size_t index = hash(address);
ASSERT(!(index & 1));
Address cachePage = roundToBlinkPageStart(address);
m_entries[index + 1] = m_entries[index];
m_entries[index] = Entry(cachePage, entry);
}
// These should not be needed, but it seems impossible to persuade clang to
// instantiate the template functions and export them from a shared library, so
// we add these in the non-templated subclass, which does not have that issue.
void HeapContainsCache::addEntry(Address address, BaseHeapPage* page)
{
HeapExtentCache<PositiveEntry>::addEntry(address, page);
}
BaseHeapPage* HeapContainsCache::lookup(Address address)
{
return HeapExtentCache<PositiveEntry>::lookup(address);
}
void Heap::flushHeapDoesNotContainCache()
{
s_heapDoesNotContainCache->flush();
}
void CallbackStack::init(CallbackStack** first)
{
// The stacks are chained, so we start by setting this to null as terminator.
*first = 0;
*first = new CallbackStack(first);
}
void CallbackStack::shutdown(CallbackStack** first)
{
CallbackStack* next;
for (CallbackStack* current = *first; current; current = next) {
next = current->m_next;
delete current;
}
*first = 0;
}
CallbackStack::~CallbackStack()
{
#if ENABLE(ASSERT)
clearUnused();
#endif
}
void CallbackStack::clearUnused()
{
for (size_t i = 0; i < bufferSize; i++)
m_buffer[i] = Item(0, 0);
}
bool CallbackStack::isEmpty()
{
return currentBlockIsEmpty() && !m_next;
}
CallbackStack* CallbackStack::takeCallbacks(CallbackStack** first)
{
// If there is a full next block unlink and return it.
if (m_next) {
CallbackStack* result = m_next;
m_next = result->m_next;
result->m_next = 0;
return result;
}
// Only the current block is in the stack. If the current block is
// empty return 0.
if (currentBlockIsEmpty())
return 0;
// The current block is not empty. Return this block and insert a
// new empty block as the marking stack.
*first = 0;
*first = new CallbackStack(first);
return this;
}
template<CallbackInvocationMode Mode>
bool CallbackStack::popAndInvokeCallback(CallbackStack** first, Visitor* visitor)
{
if (currentBlockIsEmpty()) {
if (!m_next) {
#if ENABLE(ASSERT)
clearUnused();
#endif
return false;
}
CallbackStack* nextStack = m_next;
*first = nextStack;
delete this;
return nextStack->popAndInvokeCallback<Mode>(first, visitor);
}
Item* item = --m_current;
// If the object being traced is located on a page which is dead don't
// trace it. This can happen when a conservative GC kept a dead object
// alive which pointed to a (now gone) object on the cleaned up page.
// Also if doing a thread local GC don't trace objects that are located
// on other thread's heaps, ie. pages where the terminating flag is not
// set.
BaseHeapPage* heapPage = pageHeaderFromObject(item->object());
if (Mode == GlobalMarking && heapPage->orphaned()) {
// When doing a global GC we should only get a trace callback to an orphaned
// page if the GC is conservative. If it is not conservative there is
// a bug in the code where we have a dangling pointer to a page
// on the dead thread.
RELEASE_ASSERT(Heap::lastGCWasConservative());
heapPage->setTracedAfterOrphaned();
return true;
}
if (Mode == ThreadLocalMarking && (heapPage->orphaned() || !heapPage->terminating()))
return true;
// For WeaknessProcessing we should never reach orphaned pages since
// they should never be registered as objects on orphaned pages are not
// traced. We cannot assert this here since we might have an off-heap
// collection. However we assert it in Heap::pushWeakObjectPointerCallback.
VisitorCallback callback = item->callback();
#if ENABLE(GC_PROFILE_MARKING)
if (ThreadState::isAnyThreadInGC()) // weak-processing will also use popAndInvokeCallback
visitor->setHostInfo(item->object(), classOf(item->object()));
#endif
callback(visitor, item->object());
return true;
}
void CallbackStack::invokeCallbacks(CallbackStack** first, Visitor* visitor)
{
CallbackStack* stack = 0;
// The first block is the only one where new ephemerons are added, so we
// call the callbacks on that last, to catch any new ephemerons discovered
// in the callbacks.
// However, if enough ephemerons were added, we may have a new block that
// has been prepended to the chain. This will be very rare, but we can
// handle the situation by starting again and calling all the callbacks
// a second time.
while (stack != *first) {
stack = *first;
stack->invokeOldestCallbacks(visitor);
}
}
void CallbackStack::invokeOldestCallbacks(Visitor* visitor)
{
// Recurse first (bufferSize at a time) so we get to the newly added entries
// last.
if (m_next)
m_next->invokeOldestCallbacks(visitor);
// This loop can tolerate entries being added by the callbacks after
// iteration starts.
for (unsigned i = 0; m_buffer + i < m_current; i++) {
Item& item = m_buffer[i];
// We don't need to check for orphaned pages when popping an ephemeron
// callback since the callback is only pushed after the object containing
// it has been traced. There are basically three cases to consider:
// 1. Member<EphemeronCollection>
// 2. EphemeronCollection is part of a containing object
// 3. EphemeronCollection is a value object in a collection
//
// Ad. 1. In this case we push the start of the ephemeron on the
// marking stack and do the orphaned page check when popping it off
// the marking stack.
// Ad. 2. The containing object cannot be on an orphaned page since
// in that case we wouldn't have traced its parts. This also means
// the ephemeron collection is not on the orphaned page.
// Ad. 3. Is the same as 2. The collection containing the ephemeron
// collection as a value object cannot be on an orphaned page since
// it would not have traced its values in that case.
item.callback()(visitor, item.object());
}
}
#if ENABLE(ASSERT)
bool CallbackStack::hasCallbackForObject(const void* object)
{
for (unsigned i = 0; m_buffer + i < m_current; i++) {
Item* item = &m_buffer[i];
if (item->object() == object) {
return true;
}
}
if (m_next)
return m_next->hasCallbackForObject(object);
return false;
}
#endif
// The marking mutex is used to ensure sequential access to data
// structures during marking. The marking mutex needs to be acquired
// during marking when elements are taken from the global marking
// stack or when elements are added to the global ephemeron,
// post-marking, and weak processing stacks. In debug mode the mutex
// also needs to be acquired when asserts use the heap contains
// caches.
static Mutex& markingMutex()
{
AtomicallyInitializedStatic(Mutex&, mutex = *new Mutex);
return mutex;
}
static ThreadCondition& markingCondition()
{
AtomicallyInitializedStatic(ThreadCondition&, condition = *new ThreadCondition);
return condition;
}
static void markNoTracingCallback(Visitor* visitor, void* object)
{
visitor->markNoTracing(object);
}
class MarkingVisitor : public Visitor {
public:
#if ENABLE(GC_PROFILE_MARKING)
typedef HashSet<uintptr_t> LiveObjectSet;
typedef HashMap<String, LiveObjectSet> LiveObjectMap;
typedef HashMap<uintptr_t, std::pair<uintptr_t, String> > ObjectGraph;
#endif
MarkingVisitor(CallbackStack** markingStack) : m_markingStack(markingStack)
{
}
inline void visitHeader(HeapObjectHeader* header, const void* objectPointer, TraceCallback callback)
{
ASSERT(header);
#if ENABLE(ASSERT)
{
// Check that we are not marking objects that are outside
// the heap by calling Heap::contains. However we cannot
// call Heap::contains when outside a GC and we call mark
// when doing weakness for ephemerons. Hence we only check
// when called within.
MutexLocker locker(markingMutex());
ASSERT(!ThreadState::isAnyThreadInGC() || Heap::containedInHeapOrOrphanedPage(header));
}
#endif
ASSERT(objectPointer);
if (header->isMarked())
return;
header->mark();
#if ENABLE(GC_PROFILE_MARKING)
MutexLocker locker(objectGraphMutex());
String className(classOf(objectPointer));
{
LiveObjectMap::AddResult result = currentlyLive().add(className, LiveObjectSet());
result.storedValue->value.add(reinterpret_cast<uintptr_t>(objectPointer));
}
ObjectGraph::AddResult result = objectGraph().add(reinterpret_cast<uintptr_t>(objectPointer), std::make_pair(reinterpret_cast<uintptr_t>(m_hostObject), m_hostName));
ASSERT(result.isNewEntry);
// fprintf(stderr, "%s[%p] -> %s[%p]\n", m_hostName.ascii().data(), m_hostObject, className.ascii().data(), objectPointer);
#endif
if (callback)
Heap::pushTraceCallback(m_markingStack, const_cast<void*>(objectPointer), callback);
}
virtual void mark(HeapObjectHeader* header, TraceCallback callback) OVERRIDE
{
// We need both the HeapObjectHeader and FinalizedHeapObjectHeader
// version to correctly find the payload.
visitHeader(header, header->payload(), callback);
}
virtual void mark(FinalizedHeapObjectHeader* header, TraceCallback callback) OVERRIDE
{
// We need both the HeapObjectHeader and FinalizedHeapObjectHeader
// version to correctly find the payload.
visitHeader(header, header->payload(), callback);
}
virtual void mark(const void* objectPointer, TraceCallback callback) OVERRIDE
{
if (!objectPointer)
return;
FinalizedHeapObjectHeader* header = FinalizedHeapObjectHeader::fromPayload(objectPointer);
visitHeader(header, header->payload(), callback);
}
virtual void registerDelayedMarkNoTracing(const void* object) OVERRIDE
{
Heap::pushPostMarkingCallback(const_cast<void*>(object), markNoTracingCallback);
}
virtual void registerWeakMembers(const void* closure, const void* containingObject, WeakPointerCallback callback) OVERRIDE
{
Heap::pushWeakObjectPointerCallback(const_cast<void*>(closure), const_cast<void*>(containingObject), callback);
}
virtual void registerWeakTable(const void* closure, EphemeronCallback iterationCallback, EphemeronCallback iterationDoneCallback)
{
Heap::registerWeakTable(const_cast<void*>(closure), iterationCallback, iterationDoneCallback);
}
#if ENABLE(ASSERT)
virtual bool weakTableRegistered(const void* closure)
{
return Heap::weakTableRegistered(closure);
}
#endif
virtual bool isMarked(const void* objectPointer) OVERRIDE
{
return FinalizedHeapObjectHeader::fromPayload(objectPointer)->isMarked();
}
// This macro defines the necessary visitor methods for typed heaps
#define DEFINE_VISITOR_METHODS(Type) \
virtual void mark(const Type* objectPointer, TraceCallback callback) OVERRIDE \
{ \
if (!objectPointer) \
return; \
HeapObjectHeader* header = \
HeapObjectHeader::fromPayload(objectPointer); \
visitHeader(header, header->payload(), callback); \
} \
virtual bool isMarked(const Type* objectPointer) OVERRIDE \
{ \
return HeapObjectHeader::fromPayload(objectPointer)->isMarked(); \
}
FOR_EACH_TYPED_HEAP(DEFINE_VISITOR_METHODS)
#undef DEFINE_VISITOR_METHODS
#if ENABLE(GC_PROFILE_MARKING)
void reportStats()
{
fprintf(stderr, "\n---------- AFTER MARKING -------------------\n");
for (LiveObjectMap::iterator it = currentlyLive().begin(), end = currentlyLive().end(); it != end; ++it) {
fprintf(stderr, "%s %u", it->key.ascii().data(), it->value.size());
if (it->key == "blink::Document")
reportStillAlive(it->value, previouslyLive().get(it->key));
fprintf(stderr, "\n");
}
previouslyLive().swap(currentlyLive());
currentlyLive().clear();
for (HashSet<uintptr_t>::iterator it = objectsToFindPath().begin(), end = objectsToFindPath().end(); it != end; ++it) {
dumpPathToObjectFromObjectGraph(objectGraph(), *it);
}
}
static void reportStillAlive(LiveObjectSet current, LiveObjectSet previous)
{
int count = 0;
fprintf(stderr, " [previously %u]", previous.size());
for (LiveObjectSet::iterator it = current.begin(), end = current.end(); it != end; ++it) {
if (previous.find(*it) == previous.end())
continue;
count++;
}
if (!count)
return;
fprintf(stderr, " {survived 2GCs %d: ", count);
for (LiveObjectSet::iterator it = current.begin(), end = current.end(); it != end; ++it) {
if (previous.find(*it) == previous.end())
continue;
fprintf(stderr, "%ld", *it);
if (--count)
fprintf(stderr, ", ");
}
ASSERT(!count);
fprintf(stderr, "}");
}
static void dumpPathToObjectFromObjectGraph(const ObjectGraph& graph, uintptr_t target)
{
ObjectGraph::const_iterator it = graph.find(target);
if (it == graph.end())
return;
fprintf(stderr, "Path to %lx of %s\n", target, classOf(reinterpret_cast<const void*>(target)).ascii().data());
while (it != graph.end()) {
fprintf(stderr, "<- %lx of %s\n", it->value.first, it->value.second.utf8().data());
it = graph.find(it->value.first);
}
fprintf(stderr, "\n");
}
static void dumpPathToObjectOnNextGC(void* p)
{
objectsToFindPath().add(reinterpret_cast<uintptr_t>(p));
}
static Mutex& objectGraphMutex()
{
AtomicallyInitializedStatic(Mutex&, mutex = *new Mutex);
return mutex;
}
static LiveObjectMap& previouslyLive()
{
DEFINE_STATIC_LOCAL(LiveObjectMap, map, ());
return map;
}
static LiveObjectMap& currentlyLive()
{
DEFINE_STATIC_LOCAL(LiveObjectMap, map, ());
return map;
}
static ObjectGraph& objectGraph()
{
DEFINE_STATIC_LOCAL(ObjectGraph, graph, ());
return graph;
}
static HashSet<uintptr_t>& objectsToFindPath()
{
DEFINE_STATIC_LOCAL(HashSet<uintptr_t>, set, ());
return set;
}
#endif
protected:
virtual void registerWeakCell(void** cell, WeakPointerCallback callback) OVERRIDE
{
Heap::pushWeakCellPointerCallback(cell, callback);
}
private:
CallbackStack** m_markingStack;
};
void Heap::init()
{
ThreadState::init();
CallbackStack::init(&s_markingStack);
CallbackStack::init(&s_postMarkingCallbackStack);
CallbackStack::init(&s_weakCallbackStack);
CallbackStack::init(&s_ephemeronStack);
s_heapDoesNotContainCache = new HeapDoesNotContainCache();
s_markingVisitor = new MarkingVisitor(&s_markingStack);
s_freePagePool = new FreePagePool();
s_orphanedPagePool = new OrphanedPagePool();
s_markingThreads = new Vector<OwnPtr<blink::WebThread> >();
}
void Heap::shutdown()
{
s_shutdownCalled = true;
ThreadState::shutdownHeapIfNecessary();
}
void Heap::doShutdown()
{
// We don't want to call doShutdown() twice.
if (!s_markingVisitor)
return;
ASSERT(!ThreadState::isAnyThreadInGC());
ASSERT(!ThreadState::attachedThreads().size());
delete s_markingThreads;
s_markingThreads = 0;
delete s_markingVisitor;
s_markingVisitor = 0;
delete s_heapDoesNotContainCache;
s_heapDoesNotContainCache = 0;
delete s_freePagePool;
s_freePagePool = 0;
delete s_orphanedPagePool;
s_orphanedPagePool = 0;
CallbackStack::shutdown(&s_weakCallbackStack);
CallbackStack::shutdown(&s_postMarkingCallbackStack);
CallbackStack::shutdown(&s_markingStack);
CallbackStack::shutdown(&s_ephemeronStack);
ThreadState::shutdown();
}
BaseHeapPage* Heap::contains(Address address)
{
ASSERT(ThreadState::isAnyThreadInGC());
ThreadState::AttachedThreadStateSet& threads = ThreadState::attachedThreads();
for (ThreadState::AttachedThreadStateSet::iterator it = threads.begin(), end = threads.end(); it != end; ++it) {
BaseHeapPage* page = (*it)->contains(address);
if (page)
return page;
}
return 0;
}
#if ENABLE(ASSERT)
bool Heap::containedInHeapOrOrphanedPage(void* object)
{
return contains(object) || orphanedPagePool()->contains(object);
}
#endif
Address Heap::checkAndMarkPointer(Visitor* visitor, Address address)
{
ASSERT(ThreadState::isAnyThreadInGC());
#if !ENABLE(ASSERT)
if (s_heapDoesNotContainCache->lookup(address))
return 0;
#endif
ThreadState::AttachedThreadStateSet& threads = ThreadState::attachedThreads();
for (ThreadState::AttachedThreadStateSet::iterator it = threads.begin(), end = threads.end(); it != end; ++it) {
if ((*it)->checkAndMarkPointer(visitor, address)) {
// Pointer was in a page of that thread. If it actually pointed
// into an object then that object was found and marked.
ASSERT(!s_heapDoesNotContainCache->lookup(address));
s_lastGCWasConservative = true;
return address;
}
}
#if !ENABLE(ASSERT)
s_heapDoesNotContainCache->addEntry(address, true);
#else
if (!s_heapDoesNotContainCache->lookup(address))
s_heapDoesNotContainCache->addEntry(address, true);
#endif
return 0;
}
#if ENABLE(GC_PROFILE_MARKING)
const GCInfo* Heap::findGCInfo(Address address)
{
return ThreadState::findGCInfoFromAllThreads(address);
}
#endif
#if ENABLE(GC_PROFILE_MARKING)
void Heap::dumpPathToObjectOnNextGC(void* p)
{
static_cast<MarkingVisitor*>(s_markingVisitor)->dumpPathToObjectOnNextGC(p);
}
String Heap::createBacktraceString()
{
int framesToShow = 3;
int stackFrameSize = 16;
ASSERT(stackFrameSize >= framesToShow);
typedef void* FramePointer;
FramePointer* stackFrame = static_cast<FramePointer*>(alloca(sizeof(FramePointer) * stackFrameSize));
WTFGetBacktrace(stackFrame, &stackFrameSize);
StringBuilder builder;
builder.append("Persistent");
bool didAppendFirstName = false;
// Skip frames before/including "blink::Persistent".
bool didSeePersistent = false;
for (int i = 0; i < stackFrameSize && framesToShow > 0; ++i) {
FrameToNameScope frameToName(stackFrame[i]);
if (!frameToName.nullableName())
continue;
if (strstr(frameToName.nullableName(), "blink::Persistent")) {
didSeePersistent = true;
continue;
}
if (!didSeePersistent)
continue;
if (!didAppendFirstName) {
didAppendFirstName = true;
builder.append(" ... Backtrace:");
}
builder.append("\n\t");
builder.append(frameToName.nullableName());
--framesToShow;
}
return builder.toString().replace("blink::", "");
}
#endif
void Heap::pushTraceCallback(CallbackStack** stack, void* object, TraceCallback callback)
{
#if ENABLE(ASSERT)
{
MutexLocker locker(markingMutex());
ASSERT(Heap::containedInHeapOrOrphanedPage(object));
}
#endif
CallbackStack::Item* slot = (*stack)->allocateEntry(stack);
*slot = CallbackStack::Item(object, callback);
}
template<CallbackInvocationMode Mode>
bool Heap::popAndInvokeTraceCallback(Visitor* visitor)
{
return s_markingStack->popAndInvokeCallback<Mode>(&s_markingStack, visitor);
}
void Heap::pushPostMarkingCallback(void* object, TraceCallback callback)
{
MutexLocker locker(markingMutex());
ASSERT(!Heap::orphanedPagePool()->contains(object));
CallbackStack::Item* slot = s_postMarkingCallbackStack->allocateEntry(&s_postMarkingCallbackStack);
*slot = CallbackStack::Item(object, callback);
}
bool Heap::popAndInvokePostMarkingCallback(Visitor* visitor)
{
return s_postMarkingCallbackStack->popAndInvokeCallback<PostMarking>(&s_postMarkingCallbackStack, visitor);
}
void Heap::pushWeakCellPointerCallback(void** cell, WeakPointerCallback callback)
{
MutexLocker locker(markingMutex());
ASSERT(!Heap::orphanedPagePool()->contains(cell));
CallbackStack::Item* slot = s_weakCallbackStack->allocateEntry(&s_weakCallbackStack);
*slot = CallbackStack::Item(cell, callback);
}
void Heap::pushWeakObjectPointerCallback(void* closure, void* object, WeakPointerCallback callback)
{
MutexLocker locker(markingMutex());
ASSERT(Heap::contains(object));
BaseHeapPage* heapPageForObject = pageHeaderFromObject(object);
ASSERT(!heapPageForObject->orphaned());
ASSERT(Heap::contains(object) == heapPageForObject);
ThreadState* state = heapPageForObject->threadState();
state->pushWeakObjectPointerCallback(closure, callback);
}
bool Heap::popAndInvokeWeakPointerCallback(Visitor* visitor)
{
return s_weakCallbackStack->popAndInvokeCallback<WeaknessProcessing>(&s_weakCallbackStack, visitor);
}
void Heap::registerWeakTable(void* table, EphemeronCallback iterationCallback, EphemeronCallback iterationDoneCallback)
{
{
MutexLocker locker(markingMutex());
// Check that the ephemeron table being pushed onto the stack is not on an
// orphaned page.
ASSERT(!Heap::orphanedPagePool()->contains(table));
CallbackStack::Item* slot = s_ephemeronStack->allocateEntry(&s_ephemeronStack);
*slot = CallbackStack::Item(table, iterationCallback);
}
// Register a post-marking callback to tell the tables that
// ephemeron iteration is complete.
pushPostMarkingCallback(table, iterationDoneCallback);
}
#if ENABLE(ASSERT)
bool Heap::weakTableRegistered(const void* table)
{
MutexLocker locker(markingMutex());
ASSERT(s_ephemeronStack);
return s_ephemeronStack->hasCallbackForObject(table);
}
#endif
void Heap::prepareForGC()
{
ASSERT(ThreadState::isAnyThreadInGC());
ThreadState::AttachedThreadStateSet& threads = ThreadState::attachedThreads();
for (ThreadState::AttachedThreadStateSet::iterator it = threads.begin(), end = threads.end(); it != end; ++it)
(*it)->prepareForGC();
}
void Heap::collectGarbage(ThreadState::StackState stackState)
{
ThreadState* state = ThreadState::current();
state->clearGCRequested();
GCScope gcScope(stackState);
// Check if we successfully parked the other threads. If not we bail out of the GC.
if (!gcScope.allThreadsParked()) {
ThreadState::current()->setGCRequested();
return;
}
if (state->isMainThread())
ScriptForbiddenScope::enter();
s_lastGCWasConservative = false;
TRACE_EVENT0("blink_gc", "Heap::collectGarbage");
TRACE_EVENT_SCOPED_SAMPLING_STATE("blink_gc", "BlinkGC");
double timeStamp = WTF::currentTimeMS();
#if ENABLE(GC_PROFILE_MARKING)
static_cast<MarkingVisitor*>(s_markingVisitor)->objectGraph().clear();
#endif
// Disallow allocation during garbage collection (but not
// during the finalization that happens when the gcScope is
// torn down).
NoAllocationScope<AnyThread> noAllocationScope;
prepareForGC();
// 1. trace persistent roots.
ThreadState::visitPersistentRoots(s_markingVisitor);
// 2. trace objects reachable from the persistent roots including ephemerons.
processMarkingStackInParallel();
// 3. trace objects reachable from the stack. We do this independent of the
// given stackState since other threads might have a different stack state.
ThreadState::visitStackRoots(s_markingVisitor);
// 4. trace objects reachable from the stack "roots" including ephemerons.
// Only do the processing if we found a pointer to an object on one of the
// thread stacks.
if (lastGCWasConservative())
processMarkingStackInParallel();
postMarkingProcessing();
globalWeakProcessing();
// After a global marking we know that any orphaned page that was not reached
// cannot be reached in a subsequent GC. This is due to a thread either having
// swept its heap or having done a "poor mans sweep" in prepareForGC which marks
// objects that are dead, but not swept in the previous GC as dead. In this GC's
// marking we check that any object marked as dead is not traced. E.g. via a
// conservatively found pointer or a programming error with an object containing
// a dangling pointer.
orphanedPagePool()->decommitOrphanedPages();
#if ENABLE(GC_PROFILE_MARKING)
static_cast<MarkingVisitor*>(s_markingVisitor)->reportStats();
#endif
if (blink::Platform::current()) {
uint64_t objectSpaceSize;
uint64_t allocatedSpaceSize;
getHeapSpaceSize(&objectSpaceSize, &allocatedSpaceSize);
blink::Platform::current()->histogramCustomCounts("BlinkGC.CollectGarbage", WTF::currentTimeMS() - timeStamp, 0, 10 * 1000, 50);
blink::Platform::current()->histogramCustomCounts("BlinkGC.TotalObjectSpace", objectSpaceSize / 1024, 0, 4 * 1024 * 1024, 50);
blink::Platform::current()->histogramCustomCounts("BlinkGC.TotalAllocatedSpace", allocatedSpaceSize / 1024, 0, 4 * 1024 * 1024, 50);
}
if (state->isMainThread())
ScriptForbiddenScope::exit();
}
void Heap::collectGarbageForTerminatingThread(ThreadState* state)
{
// We explicitly do not enter a safepoint while doing thread specific
// garbage collection since we don't want to allow a global GC at the
// same time as a thread local GC.
{
NoAllocationScope<AnyThread> noAllocationScope;
state->enterGC();
state->prepareForGC();
// 1. trace the thread local persistent roots. For thread local GCs we
// don't trace the stack (ie. no conservative scanning) since this is
// only called during thread shutdown where there should be no objects
// on the stack.
// We also assume that orphaned pages have no objects reachable from
// persistent handles on other threads or CrossThreadPersistents. The
// only cases where this could happen is if a subsequent conservative
// global GC finds a "pointer" on the stack or due to a programming
// error where an object has a dangling cross-thread pointer to an
// object on this heap.
state->visitPersistents(s_markingVisitor);
// 2. trace objects reachable from the thread's persistent roots
// including ephemerons.
processMarkingStack<ThreadLocalMarking>();
postMarkingProcessing();
globalWeakProcessing();
state->leaveGC();
}
state->performPendingSweep();
}
void Heap::processMarkingStackEntries(int* runningMarkingThreads)
{
CallbackStack* stack = 0;
MarkingVisitor visitor(&stack);
{
MutexLocker locker(markingMutex());
stack = s_markingStack->takeCallbacks(&s_markingStack);
}
while (stack) {
while (stack->popAndInvokeCallback<GlobalMarking>(&stack, &visitor)) { }
delete stack;
{
MutexLocker locker(markingMutex());
stack = s_markingStack->takeCallbacks(&s_markingStack);
}
}
{
MutexLocker locker(markingMutex());
if (!--(*runningMarkingThreads))
markingCondition().signal();
}
}
void Heap::processMarkingStackOnMultipleThreads()
{
}
void Heap::processMarkingStackInParallel()
{
static const int numberOfBlocksForParallelMarking = 2;
// Ephemeron fixed point loop run on the garbage collecting thread.
do {
// Iteratively mark all objects that are reachable from the objects
// currently pushed onto the marking stack. Do so in parallel if there
// are multiple blocks on the global marking stack.
if (s_markingStack->numberOfBlocksExceeds(numberOfBlocksForParallelMarking)) {
processMarkingStackOnMultipleThreads();
} else {
while (popAndInvokeTraceCallback<GlobalMarking>(s_markingVisitor)) { }
}
// Mark any strong pointers that have now become reachable in ephemeron
// maps.
CallbackStack::invokeCallbacks(&s_ephemeronStack, s_markingVisitor);
// Rerun loop if ephemeron processing queued more objects for tracing.
} while (!s_markingStack->isEmpty());
}
template<CallbackInvocationMode Mode>
void Heap::processMarkingStack()
{
// Ephemeron fixed point loop.
do {
// Iteratively mark all objects that are reachable from the objects
// currently pushed onto the marking stack. If Mode is ThreadLocalMarking
// don't continue tracing if the trace hits an object on another thread's
// heap.
while (popAndInvokeTraceCallback<Mode>(s_markingVisitor)) { }
// Mark any strong pointers that have now become reachable in ephemeron
// maps.
CallbackStack::invokeCallbacks(&s_ephemeronStack, s_markingVisitor);
// Rerun loop if ephemeron processing queued more objects for tracing.
} while (!s_markingStack->isEmpty());
}
void Heap::postMarkingProcessing()
{
// Call post-marking callbacks including:
// 1. the ephemeronIterationDone callbacks on weak tables to do cleanup
// (specifically to clear the queued bits for weak hash tables), and
// 2. the markNoTracing callbacks on collection backings to mark them
// if they are only reachable from their front objects.
while (popAndInvokePostMarkingCallback(s_markingVisitor)) { }
CallbackStack::clear(&s_ephemeronStack);
// Post-marking callbacks should not trace any objects and
// therefore the marking stack should be empty after the
// post-marking callbacks.
ASSERT(s_markingStack->isEmpty());
}
void Heap::globalWeakProcessing()
{
// Call weak callbacks on objects that may now be pointing to dead
// objects.
while (popAndInvokeWeakPointerCallback(s_markingVisitor)) { }
// It is not permitted to trace pointers of live objects in the weak
// callback phase, so the marking stack should still be empty here.
ASSERT(s_markingStack->isEmpty());
}
void Heap::collectAllGarbage()
{
// FIXME: oilpan: we should perform a single GC and everything
// should die. Unfortunately it is not the case for all objects
// because the hierarchy was not completely moved to the heap and
// some heap allocated objects own objects that contain persistents
// pointing to other heap allocated objects.
for (int i = 0; i < 5; i++)
collectGarbage(ThreadState::NoHeapPointersOnStack);
}
void Heap::setForcePreciseGCForTesting()
{
ThreadState::current()->setForcePreciseGCForTesting(true);
}
template<typename Header>
void ThreadHeap<Header>::prepareHeapForTermination()
{
for (HeapPage<Header>* page = m_firstPage; page; page = page->next()) {
page->setTerminating();
}
for (LargeHeapObject<Header>* current = m_firstLargeHeapObject; current; current = current->next()) {
current->setTerminating();
}
}
template<typename Header>
BaseHeap* ThreadHeap<Header>::split(int numberOfNormalPages)
{
// Create a new split off thread heap containing
// |numberOfNormalPages| of the pages of this ThreadHeap for
// parallel sweeping. The split off thread heap will be merged
// with this heap at the end of sweeping and the temporary
// ThreadHeap object will be deallocated after the merge.
ASSERT(numberOfNormalPages > 0);
ThreadHeap<Header>* splitOff = new ThreadHeap(m_threadState, m_index);
HeapPage<Header>* splitPoint = m_firstPage;
for (int i = 1; i < numberOfNormalPages; i++)
splitPoint = splitPoint->next();
splitOff->m_firstPage = m_firstPage;
m_firstPage = splitPoint->m_next;
splitOff->m_mergePoint = splitPoint;
splitOff->m_numberOfNormalPages = numberOfNormalPages;
m_numberOfNormalPages -= numberOfNormalPages;
splitPoint->m_next = 0;
return splitOff;
}
template<typename Header>
void ThreadHeap<Header>::merge(BaseHeap* splitOffBase)
{
ThreadHeap<Header>* splitOff = static_cast<ThreadHeap<Header>*>(splitOffBase);
// If the mergePoint is zero all split off pages became empty in
// this round and we don't have to merge. There are no pages and
// nothing on the freelists.
ASSERT(splitOff->m_mergePoint || splitOff->m_numberOfNormalPages == 0);
if (splitOff->m_mergePoint) {
// Link the split off pages into the beginning of the list again.
splitOff->m_mergePoint->m_next = m_firstPage;
m_firstPage = splitOff->m_firstPage;
m_numberOfNormalPages += splitOff->m_numberOfNormalPages;
splitOff->m_firstPage = 0;
// Merge free lists.
for (size_t i = 0; i < blinkPageSizeLog2; i++) {
if (!m_freeLists[i]) {
m_freeLists[i] = splitOff->m_freeLists[i];
} else if (splitOff->m_freeLists[i]) {
m_lastFreeListEntries[i]->append(splitOff->m_freeLists[i]);
m_lastFreeListEntries[i] = splitOff->m_lastFreeListEntries[i];
}
}
}
delete splitOffBase;
}
void Heap::getHeapSpaceSize(uint64_t* objectSpaceSize, uint64_t* allocatedSpaceSize)
{
*objectSpaceSize = 0;
*allocatedSpaceSize = 0;
ASSERT(ThreadState::isAnyThreadInGC());
ThreadState::AttachedThreadStateSet& threads = ThreadState::attachedThreads();
typedef ThreadState::AttachedThreadStateSet::iterator ThreadStateIterator;
for (ThreadStateIterator it = threads.begin(), end = threads.end(); it != end; ++it) {
*objectSpaceSize += (*it)->stats().totalObjectSpace();
*allocatedSpaceSize += (*it)->stats().totalAllocatedSpace();
}
}
void Heap::getStats(HeapStats* stats)
{
stats->clear();
ASSERT(ThreadState::isAnyThreadInGC());
ThreadState::AttachedThreadStateSet& threads = ThreadState::attachedThreads();
typedef ThreadState::AttachedThreadStateSet::iterator ThreadStateIterator;
for (ThreadStateIterator it = threads.begin(), end = threads.end(); it != end; ++it) {
HeapStats temp;
(*it)->getStats(temp);
stats->add(&temp);
}
}
#if ENABLE(ASSERT)
bool Heap::isConsistentForSweeping()
{
ASSERT(ThreadState::isAnyThreadInGC());
ThreadState::AttachedThreadStateSet& threads = ThreadState::attachedThreads();
for (ThreadState::AttachedThreadStateSet::iterator it = threads.begin(), end = threads.end(); it != end; ++it) {
if (!(*it)->isConsistentForSweeping())
return false;
}
return true;
}
#endif
void Heap::makeConsistentForSweeping()
{
ASSERT(ThreadState::isAnyThreadInGC());
ThreadState::AttachedThreadStateSet& threads = ThreadState::attachedThreads();
for (ThreadState::AttachedThreadStateSet::iterator it = threads.begin(), end = threads.end(); it != end; ++it)
(*it)->makeConsistentForSweeping();
}
void HeapAllocator::backingFree(void* address)
{
if (!address || ThreadState::isAnyThreadInGC())
return;
ThreadState* state = ThreadState::current();
if (state->isSweepInProgress())
return;
// Don't promptly free large objects because their page is never reused
// and don't free backings allocated on other threads.
BaseHeapPage* page = pageHeaderFromObject(address);
if (page->isLargeObject() || page->threadState() != state)
return;
typedef HeapIndexTrait<CollectionBackingHeap> HeapTraits;
typedef HeapTraits::HeapType HeapType;
typedef HeapTraits::HeaderType HeaderType;
HeaderType* header = HeaderType::fromPayload(address);
header->checkHeader();
const GCInfo* gcInfo = header->gcInfo();
int heapIndex = HeapTraits::index(gcInfo->hasFinalizer());
HeapType* heap = static_cast<HeapType*>(state->heap(heapIndex));
heap->promptlyFreeObject(header);
}
// Force template instantiations for the types that we need.
template class HeapPage<FinalizedHeapObjectHeader>;
template class HeapPage<HeapObjectHeader>;
template class ThreadHeap<FinalizedHeapObjectHeader>;
template class ThreadHeap<HeapObjectHeader>;
template bool CallbackStack::popAndInvokeCallback<GlobalMarking>(CallbackStack**, Visitor*);
template bool CallbackStack::popAndInvokeCallback<ThreadLocalMarking>(CallbackStack**, Visitor*);
template bool CallbackStack::popAndInvokeCallback<WeaknessProcessing>(CallbackStack**, Visitor*);
Visitor* Heap::s_markingVisitor;
Vector<OwnPtr<blink::WebThread> >* Heap::s_markingThreads;
CallbackStack* Heap::s_markingStack;
CallbackStack* Heap::s_postMarkingCallbackStack;
CallbackStack* Heap::s_weakCallbackStack;
CallbackStack* Heap::s_ephemeronStack;
HeapDoesNotContainCache* Heap::s_heapDoesNotContainCache;
bool Heap::s_shutdownCalled = false;
bool Heap::s_lastGCWasConservative = false;
FreePagePool* Heap::s_freePagePool;
OrphanedPagePool* Heap::s_orphanedPagePool;
}
Reference in New Issue View Git Blame Copy Permalink