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|
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
* vim: set ts=8 sts=2 et sw=2 tw=80:
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "gc/Allocator.h"
#include "mozilla/DebugOnly.h"
#include "mozilla/OperatorNewExtensions.h"
#include "mozilla/TimeStamp.h"
#include "gc/GCInternals.h"
#include "gc/GCLock.h"
#include "gc/GCProbes.h"
#include "gc/Nursery.h"
#include "threading/CpuCount.h"
#include "util/Poison.h"
#include "vm/BigIntType.h"
#include "vm/JSContext.h"
#include "vm/Runtime.h"
#include "vm/StringType.h"
#include "gc/ArenaList-inl.h"
#include "gc/Heap-inl.h"
#include "gc/PrivateIterators-inl.h"
#include "vm/JSContext-inl.h"
using mozilla::TimeDuration;
using mozilla::TimeStamp;
using namespace js;
using namespace js::gc;
// Return a Heap value that can be compared numerically with an
// allocation's requested heap to determine whether to allocate in the nursery
// or the tenured heap.
//
// If nursery allocation is allowed this returns Heap::Tenured, meaning only
// Heap::Tenured allocations will be tenured. If nursery allocation is not
// allowed this returns Heap::Default, meaning all allocations are tenured.
static Heap MinHeapToTenure(bool allowNurseryAlloc) {
static_assert(Heap::Tenured > Heap::Default);
return allowNurseryAlloc ? Heap::Tenured : Heap::Default;
}
void Zone::setNurseryAllocFlags(bool allocObjects, bool allocStrings,
bool allocBigInts) {
allocNurseryObjects_ = allocObjects;
allocNurseryStrings_ = allocStrings;
allocNurseryBigInts_ = allocBigInts;
minObjectHeapToTenure_ = MinHeapToTenure(allocNurseryObjects());
minStringHeapToTenure_ = MinHeapToTenure(allocNurseryStrings());
minBigintHeapToTenure_ = MinHeapToTenure(allocNurseryBigInts());
}
#define INSTANTIATE_ALLOC_NURSERY_CELL(traceKind, allowGc) \
template void* \
gc::CellAllocator::AllocNurseryOrTenuredCell<traceKind, allowGc>( \
JSContext*, AllocKind, size_t, gc::Heap, AllocSite*);
INSTANTIATE_ALLOC_NURSERY_CELL(JS::TraceKind::Object, NoGC)
INSTANTIATE_ALLOC_NURSERY_CELL(JS::TraceKind::Object, CanGC)
INSTANTIATE_ALLOC_NURSERY_CELL(JS::TraceKind::String, NoGC)
INSTANTIATE_ALLOC_NURSERY_CELL(JS::TraceKind::String, CanGC)
INSTANTIATE_ALLOC_NURSERY_CELL(JS::TraceKind::BigInt, NoGC)
INSTANTIATE_ALLOC_NURSERY_CELL(JS::TraceKind::BigInt, CanGC)
#undef INSTANTIATE_ALLOC_NURSERY_CELL
// Attempt to allocate a new cell in the nursery. If there is not enough room in
// the nursery or there is an OOM, this method will return nullptr.
template <AllowGC allowGC>
/* static */
MOZ_NEVER_INLINE void* CellAllocator::RetryNurseryAlloc(JSContext* cx,
JS::TraceKind traceKind,
AllocKind allocKind,
size_t thingSize,
AllocSite* site) {
MOZ_ASSERT(cx->isNurseryAllocAllowed());
Zone* zone = site->zone();
MOZ_ASSERT(!zone->isAtomsZone());
MOZ_ASSERT(zone->allocKindInNursery(traceKind));
Nursery& nursery = cx->nursery();
JS::GCReason reason = nursery.handleAllocationFailure();
if (reason == JS::GCReason::NO_REASON) {
void* ptr = nursery.tryAllocateCell(site, thingSize, traceKind);
MOZ_ASSERT(ptr);
return ptr;
}
// Our most common non-jit allocation path is NoGC; thus, if we fail the
// alloc and cannot GC, we *must* return nullptr here so that the caller
// will do a CanGC allocation to clear the nursery. Failing to do so will
// cause all allocations on this path to land in Tenured, and we will not
// get the benefit of the nursery.
if constexpr (!allowGC) {
return nullptr;
}
if (!cx->suppressGC) {
cx->runtime()->gc.minorGC(reason);
// Exceeding gcMaxBytes while tenuring can disable the Nursery.
if (zone->allocKindInNursery(traceKind)) {
void* ptr = cx->nursery().allocateCell(site, thingSize, traceKind);
if (ptr) {
return ptr;
}
}
}
// As a final fallback, allocate the cell in the tenured heap.
return TryNewTenuredCell<allowGC>(cx, allocKind, thingSize);
}
template void* CellAllocator::RetryNurseryAlloc<NoGC>(JSContext* cx,
JS::TraceKind traceKind,
AllocKind allocKind,
size_t thingSize,
AllocSite* site);
template void* CellAllocator::RetryNurseryAlloc<CanGC>(JSContext* cx,
JS::TraceKind traceKind,
AllocKind allocKind,
size_t thingSize,
AllocSite* site);
template <AllowGC allowGC>
void* gc::CellAllocator::AllocTenuredCell(JSContext* cx, gc::AllocKind kind,
size_t size) {
MOZ_ASSERT(!IsNurseryAllocable(kind));
MOZ_ASSERT(size == Arena::thingSize(kind));
if (!PreAllocChecks<allowGC>(cx, kind)) {
return nullptr;
}
return TryNewTenuredCell<allowGC>(cx, kind, size);
}
template void* gc::CellAllocator::AllocTenuredCell<NoGC>(JSContext*, AllocKind,
size_t);
template void* gc::CellAllocator::AllocTenuredCell<CanGC>(JSContext*, AllocKind,
size_t);
template <AllowGC allowGC>
/* static */
void* CellAllocator::TryNewTenuredCell(JSContext* cx, AllocKind kind,
size_t thingSize) {
if constexpr (allowGC) {
// Invoking the interrupt callback can fail and we can't usefully
// handle that here. Just check in case we need to collect instead.
if (cx->hasPendingInterrupt(InterruptReason::MajorGC)) {
cx->runtime()->gc.gcIfRequested();
}
}
// Bump allocate in the arena's current free-list span.
Zone* zone = cx->zone();
void* ptr = zone->arenas.freeLists().allocate(kind);
if (MOZ_UNLIKELY(!ptr)) {
// Get the next available free list and allocate out of it. This may
// acquire a new arena, which will lock the chunk list. If there are no
// chunks available it may also allocate new memory directly.
ptr = GCRuntime::refillFreeList(cx, kind);
if (MOZ_UNLIKELY(!ptr)) {
if constexpr (allowGC) {
cx->runtime()->gc.attemptLastDitchGC(cx);
ptr = TryNewTenuredCell<NoGC>(cx, kind, thingSize);
if (ptr) {
return ptr;
}
ReportOutOfMemory(cx);
}
return nullptr;
}
}
#ifdef DEBUG
CheckIncrementalZoneState(cx, ptr);
#endif
gcprobes::TenuredAlloc(ptr, kind);
// We count this regardless of the profiler's state, assuming that it costs
// just as much to count it, as to check the profiler's state and decide not
// to count it.
zone->noteTenuredAlloc();
return ptr;
}
template void* CellAllocator::TryNewTenuredCell<NoGC>(JSContext* cx,
AllocKind kind,
size_t thingSize);
template void* CellAllocator::TryNewTenuredCell<CanGC>(JSContext* cx,
AllocKind kind,
size_t thingSize);
void GCRuntime::attemptLastDitchGC(JSContext* cx) {
// Either there was no memory available for a new chunk or the heap hit its
// size limit. Try to perform an all-compartments, non-incremental, shrinking
// GC and wait for it to finish.
if (!lastLastDitchTime.IsNull() &&
TimeStamp::Now() - lastLastDitchTime <= tunables.minLastDitchGCPeriod()) {
return;
}
JS::PrepareForFullGC(cx);
gc(JS::GCOptions::Shrink, JS::GCReason::LAST_DITCH);
waitBackgroundAllocEnd();
waitBackgroundFreeEnd();
lastLastDitchTime = mozilla::TimeStamp::Now();
}
#ifdef DEBUG
static bool IsAtomsZoneKind(AllocKind kind) {
return kind == AllocKind::ATOM || kind == AllocKind::FAT_INLINE_ATOM ||
kind == AllocKind::SYMBOL;
}
#endif
#if defined(DEBUG) || defined(JS_GC_ZEAL) || defined(JS_OOM_BREAKPOINT)
static inline void CheckAllocZone(Zone* zone, AllocKind kind) {
MOZ_ASSERT_IF(zone->isAtomsZone(),
IsAtomsZoneKind(kind) || kind == AllocKind::JITCODE);
MOZ_ASSERT_IF(!zone->isAtomsZone(), !IsAtomsZoneKind(kind));
}
// This serves as a single point to perform a bunch of unrelated work that
// happens before every allocation. Performs the following testing functions:
//
// - checks we can't GC inside a JS::AutoAssertNoGC region
// - runs a zeal GC if needed
// - possibly fails the allocation for OOM testing
//
// This is a no-op in release builds.
template <AllowGC allowGC>
bool CellAllocator::PreAllocChecks(JSContext* cx, AllocKind kind) {
MOZ_ASSERT(CurrentThreadCanAccessRuntime(cx->runtime()));
CheckAllocZone(cx->zone(), kind);
// Crash if we could perform a GC action when it is not safe.
if (allowGC && !cx->suppressGC) {
cx->verifyIsSafeToGC();
}
# ifdef JS_GC_ZEAL
if constexpr (allowGC) {
GCRuntime* gc = &cx->runtime()->gc;
if (gc->needZealousGC()) {
gc->runDebugGC();
}
}
# endif
// For testing out of memory conditions.
if (js::oom::ShouldFailWithOOM()) {
// If we are doing a fallible allocation, percolate up the OOM instead of
// reporting it.
if constexpr (allowGC) {
ReportOutOfMemory(cx);
}
return false;
}
return true;
}
template bool CellAllocator::PreAllocChecks<NoGC>(JSContext* cx,
AllocKind kind);
template bool CellAllocator::PreAllocChecks<CanGC>(JSContext* cx,
AllocKind kind);
#endif // DEBUG || JS_GC_ZEAL || JS_OOM_BREAKPOINT
#ifdef DEBUG
/* static */
void CellAllocator::CheckIncrementalZoneState(JSContext* cx, void* ptr) {
MOZ_ASSERT(ptr);
TenuredCell* cell = reinterpret_cast<TenuredCell*>(ptr);
TenuredChunkBase* chunk = detail::GetCellChunkBase(cell);
if (cx->zone()->isGCMarkingOrSweeping()) {
MOZ_ASSERT(chunk->markBits.isMarkedBlack(cell));
} else {
MOZ_ASSERT(!chunk->markBits.isMarkedAny(cell));
}
}
#endif
void* js::gc::AllocateTenuredCellInGC(Zone* zone, AllocKind thingKind) {
void* ptr = zone->arenas.allocateFromFreeList(thingKind);
if (!ptr) {
AutoEnterOOMUnsafeRegion oomUnsafe;
ptr = GCRuntime::refillFreeListInGC(zone, thingKind);
if (!ptr) {
oomUnsafe.crash(ChunkSize, "Failed to allocate new chunk during GC");
}
}
return ptr;
}
// /////////// Arena -> Thing Allocator //////////////////////////////////////
void GCRuntime::startBackgroundAllocTaskIfIdle() {
AutoLockHelperThreadState lock;
if (!allocTask.wasStarted(lock)) {
// Join the previous invocation of the task. This will return immediately
// if the thread has never been started.
allocTask.joinWithLockHeld(lock);
allocTask.startWithLockHeld(lock);
}
}
/* static */
void* GCRuntime::refillFreeList(JSContext* cx, AllocKind thingKind) {
MOZ_ASSERT(cx->zone()->arenas.freeLists().isEmpty(thingKind));
// It should not be possible to allocate on the main thread while we are
// inside a GC.
MOZ_ASSERT(!JS::RuntimeHeapIsBusy(), "allocating while under GC");
return cx->zone()->arenas.refillFreeListAndAllocate(
thingKind, ShouldCheckThresholds::CheckThresholds);
}
/* static */
void* GCRuntime::refillFreeListInGC(Zone* zone, AllocKind thingKind) {
// Called by compacting GC to refill a free list while we are in a GC.
MOZ_ASSERT(JS::RuntimeHeapIsCollecting());
MOZ_ASSERT_IF(!JS::RuntimeHeapIsMinorCollecting(),
!zone->runtimeFromMainThread()->gc.isBackgroundSweeping());
return zone->arenas.refillFreeListAndAllocate(
thingKind, ShouldCheckThresholds::DontCheckThresholds);
}
void* ArenaLists::refillFreeListAndAllocate(
AllocKind thingKind, ShouldCheckThresholds checkThresholds) {
MOZ_ASSERT(freeLists().isEmpty(thingKind));
JSRuntime* rt = runtimeFromAnyThread();
mozilla::Maybe<AutoLockGCBgAlloc> maybeLock;
// See if we can proceed without taking the GC lock.
if (concurrentUse(thingKind) != ConcurrentUse::None) {
maybeLock.emplace(rt);
}
Arena* arena = arenaList(thingKind).takeNextArena();
if (arena) {
// Empty arenas should be immediately freed.
MOZ_ASSERT(!arena->isEmpty());
return freeLists().setArenaAndAllocate(arena, thingKind);
}
// Parallel threads have their own ArenaLists, but chunks are shared;
// if we haven't already, take the GC lock now to avoid racing.
if (maybeLock.isNothing()) {
maybeLock.emplace(rt);
}
TenuredChunk* chunk = rt->gc.pickChunk(maybeLock.ref());
if (!chunk) {
return nullptr;
}
// Although our chunk should definitely have enough space for another arena,
// there are other valid reasons why TenuredChunk::allocateArena() may fail.
arena = rt->gc.allocateArena(chunk, zone_, thingKind, checkThresholds,
maybeLock.ref());
if (!arena) {
return nullptr;
}
ArenaList& al = arenaList(thingKind);
MOZ_ASSERT(al.isCursorAtEnd());
al.insertBeforeCursor(arena);
return freeLists().setArenaAndAllocate(arena, thingKind);
}
inline void* FreeLists::setArenaAndAllocate(Arena* arena, AllocKind kind) {
#ifdef DEBUG
auto* old = freeLists_[kind];
if (!old->isEmpty()) {
old->getArena()->checkNoMarkedFreeCells();
}
#endif
FreeSpan* span = arena->getFirstFreeSpan();
freeLists_[kind] = span;
Zone* zone = arena->zone;
if (MOZ_UNLIKELY(zone->isGCMarkingOrSweeping())) {
arena->arenaAllocatedDuringGC();
}
TenuredCell* thing = span->allocate(Arena::thingSize(kind));
MOZ_ASSERT(thing); // This allocation is infallible.
return thing;
}
void Arena::arenaAllocatedDuringGC() {
// Ensure that anything allocated during the mark or sweep phases of an
// incremental GC will be marked black by pre-marking all free cells in the
// arena we are about to allocate from.
MOZ_ASSERT(zone->isGCMarkingOrSweeping());
for (ArenaFreeCellIter cell(this); !cell.done(); cell.next()) {
MOZ_ASSERT(!cell->isMarkedAny());
cell->markBlack();
}
}
// /////////// TenuredChunk -> Arena Allocator ///////////////////////////////
bool GCRuntime::wantBackgroundAllocation(const AutoLockGC& lock) const {
// To minimize memory waste, we do not want to run the background chunk
// allocation if we already have some empty chunks or when the runtime has
// a small heap size (and therefore likely has a small growth rate).
return allocTask.enabled() &&
emptyChunks(lock).count() < minEmptyChunkCount(lock) &&
(fullChunks(lock).count() + availableChunks(lock).count()) >= 4;
}
Arena* GCRuntime::allocateArena(TenuredChunk* chunk, Zone* zone,
AllocKind thingKind,
ShouldCheckThresholds checkThresholds,
const AutoLockGC& lock) {
MOZ_ASSERT(chunk->hasAvailableArenas());
// Fail the allocation if we are over our heap size limits.
if ((checkThresholds != ShouldCheckThresholds::DontCheckThresholds) &&
(heapSize.bytes() >= tunables.gcMaxBytes())) {
return nullptr;
}
Arena* arena = chunk->allocateArena(this, zone, thingKind, lock);
zone->gcHeapSize.addGCArena(heapSize);
// Trigger an incremental slice if needed.
if (checkThresholds != ShouldCheckThresholds::DontCheckThresholds) {
maybeTriggerGCAfterAlloc(zone);
}
return arena;
}
Arena* TenuredChunk::allocateArena(GCRuntime* gc, Zone* zone,
AllocKind thingKind,
const AutoLockGC& lock) {
if (info.numArenasFreeCommitted == 0) {
commitOnePage(gc);
MOZ_ASSERT(info.numArenasFreeCommitted == ArenasPerPage);
}
MOZ_ASSERT(info.numArenasFreeCommitted > 0);
Arena* arena = fetchNextFreeArena(gc);
arena->init(zone, thingKind, lock);
updateChunkListAfterAlloc(gc, lock);
verify();
return arena;
}
template <size_t N>
static inline size_t FindFirstBitSet(
const mozilla::BitSet<N, uint32_t>& bitset) {
MOZ_ASSERT(!bitset.IsEmpty());
const auto& words = bitset.Storage();
for (size_t i = 0; i < words.Length(); i++) {
uint32_t word = words[i];
if (word) {
return i * 32 + mozilla::CountTrailingZeroes32(word);
}
}
MOZ_CRASH("No bits found");
}
void TenuredChunk::commitOnePage(GCRuntime* gc) {
MOZ_ASSERT(info.numArenasFreeCommitted == 0);
MOZ_ASSERT(info.numArenasFree >= ArenasPerPage);
uint32_t pageIndex = FindFirstBitSet(decommittedPages);
MOZ_ASSERT(decommittedPages[pageIndex]);
if (DecommitEnabled()) {
MarkPagesInUseSoft(pageAddress(pageIndex), PageSize);
}
decommittedPages[pageIndex] = false;
for (size_t i = 0; i < ArenasPerPage; i++) {
size_t arenaIndex = pageIndex * ArenasPerPage + i;
MOZ_ASSERT(!freeCommittedArenas[arenaIndex]);
freeCommittedArenas[arenaIndex] = true;
arenas[arenaIndex].setAsNotAllocated();
++info.numArenasFreeCommitted;
gc->updateOnArenaFree();
}
verify();
}
inline void GCRuntime::updateOnFreeArenaAlloc(const TenuredChunkInfo& info) {
MOZ_ASSERT(info.numArenasFreeCommitted <= numArenasFreeCommitted);
--numArenasFreeCommitted;
}
Arena* TenuredChunk::fetchNextFreeArena(GCRuntime* gc) {
MOZ_ASSERT(info.numArenasFreeCommitted > 0);
MOZ_ASSERT(info.numArenasFreeCommitted <= info.numArenasFree);
size_t index = FindFirstBitSet(freeCommittedArenas);
MOZ_ASSERT(freeCommittedArenas[index]);
freeCommittedArenas[index] = false;
--info.numArenasFreeCommitted;
--info.numArenasFree;
gc->updateOnFreeArenaAlloc(info);
return &arenas[index];
}
// /////////// System -> TenuredChunk Allocator //////////////////////////////
TenuredChunk* GCRuntime::getOrAllocChunk(AutoLockGCBgAlloc& lock) {
TenuredChunk* chunk = emptyChunks(lock).pop();
if (chunk) {
// Reinitialize ChunkBase; arenas are all free and may or may not be
// committed.
SetMemCheckKind(chunk, sizeof(ChunkBase), MemCheckKind::MakeUndefined);
chunk->initBaseForTenuredChunk(rt);
MOZ_ASSERT(chunk->unused());
} else {
void* ptr = TenuredChunk::allocate(this);
if (!ptr) {
return nullptr;
}
chunk = TenuredChunk::emplace(ptr, this, /* allMemoryCommitted = */ true);
MOZ_ASSERT(chunk->info.numArenasFreeCommitted == 0);
}
if (wantBackgroundAllocation(lock)) {
lock.tryToStartBackgroundAllocation();
}
return chunk;
}
void GCRuntime::recycleChunk(TenuredChunk* chunk, const AutoLockGC& lock) {
#ifdef DEBUG
MOZ_ASSERT(chunk->unused());
chunk->verify();
#endif
// Poison ChunkBase to catch use after free.
AlwaysPoison(chunk, JS_FREED_CHUNK_PATTERN, sizeof(ChunkBase),
MemCheckKind::MakeNoAccess);
emptyChunks(lock).push(chunk);
}
TenuredChunk* GCRuntime::pickChunk(AutoLockGCBgAlloc& lock) {
if (availableChunks(lock).count()) {
return availableChunks(lock).head();
}
TenuredChunk* chunk = getOrAllocChunk(lock);
if (!chunk) {
return nullptr;
}
#ifdef DEBUG
chunk->verify();
MOZ_ASSERT(chunk->unused());
MOZ_ASSERT(!fullChunks(lock).contains(chunk));
MOZ_ASSERT(!availableChunks(lock).contains(chunk));
#endif
availableChunks(lock).push(chunk);
return chunk;
}
BackgroundAllocTask::BackgroundAllocTask(GCRuntime* gc, ChunkPool& pool)
: GCParallelTask(gc, gcstats::PhaseKind::NONE),
chunkPool_(pool),
enabled_(CanUseExtraThreads() && GetCPUCount() >= 2) {
// This can occur outside GCs so doesn't have a stats phase.
}
void BackgroundAllocTask::run(AutoLockHelperThreadState& lock) {
AutoUnlockHelperThreadState unlock(lock);
AutoLockGC gcLock(gc);
while (!isCancelled() && gc->wantBackgroundAllocation(gcLock)) {
TenuredChunk* chunk;
{
AutoUnlockGC unlock(gcLock);
void* ptr = TenuredChunk::allocate(gc);
if (!ptr) {
break;
}
chunk = TenuredChunk::emplace(ptr, gc, /* allMemoryCommitted = */ true);
}
chunkPool_.ref().push(chunk);
}
}
/* static */
void* TenuredChunk::allocate(GCRuntime* gc) {
void* chunk = MapAlignedPages(ChunkSize, ChunkSize);
if (!chunk) {
return nullptr;
}
gc->stats().count(gcstats::COUNT_NEW_CHUNK);
return chunk;
}
static inline bool ShouldDecommitNewChunk(bool allMemoryCommitted,
const GCSchedulingState& state) {
if (!DecommitEnabled()) {
return false;
}
return !allMemoryCommitted || !state.inHighFrequencyGCMode();
}
TenuredChunk* TenuredChunk::emplace(void* ptr, GCRuntime* gc,
bool allMemoryCommitted) {
/* The chunk may still have some regions marked as no-access. */
MOZ_MAKE_MEM_UNDEFINED(ptr, ChunkSize);
/*
* Poison the chunk. Note that decommitAllArenas() below will mark the
* arenas as inaccessible (for memory sanitizers).
*/
Poison(ptr, JS_FRESH_TENURED_PATTERN, ChunkSize, MemCheckKind::MakeUndefined);
TenuredChunk* chunk = new (mozilla::KnownNotNull, ptr) TenuredChunk(gc->rt);
if (ShouldDecommitNewChunk(allMemoryCommitted, gc->schedulingState)) {
// Decommit the arenas. We do this after poisoning so that if the OS does
// not have to recycle the pages, we still get the benefit of poisoning.
chunk->decommitAllArenas();
} else {
// The chunk metadata is initialized as decommitted regardless, to avoid
// having to initialize the arenas at this time.
chunk->initAsDecommitted();
}
chunk->verify();
return chunk;
}
void TenuredChunk::decommitAllArenas() {
MOZ_ASSERT(unused());
MarkPagesUnusedSoft(&arenas[0], ArenasPerChunk * ArenaSize);
initAsDecommitted();
}
void TenuredChunkBase::initAsDecommitted() {
// Set the state of all arenas to free and decommitted. They might not
// actually be decommitted, but in that case the re-commit operation is a
// no-op so it doesn't matter.
decommittedPages.SetAll();
freeCommittedArenas.ResetAll();
info.numArenasFree = ArenasPerChunk;
info.numArenasFreeCommitted = 0;
}
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