From 26a029d407be480d791972afb5975cf62c9360a6 Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Fri, 19 Apr 2024 02:47:55 +0200 Subject: Adding upstream version 124.0.1. Signed-off-by: Daniel Baumann --- js/src/gc/GC.cpp | 5171 ++++++++++++++++++++++++++++++++++++++++++++++++++++++ 1 file changed, 5171 insertions(+) create mode 100644 js/src/gc/GC.cpp (limited to 'js/src/gc/GC.cpp') diff --git a/js/src/gc/GC.cpp b/js/src/gc/GC.cpp new file mode 100644 index 0000000000..7ec63a571d --- /dev/null +++ b/js/src/gc/GC.cpp @@ -0,0 +1,5171 @@ +/* -*- 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/. */ + +/* + * [SMDOC] Garbage Collector + * + * This code implements an incremental mark-and-sweep garbage collector, with + * most sweeping carried out in the background on a parallel thread. + * + * Full vs. zone GC + * ---------------- + * + * The collector can collect all zones at once, or a subset. These types of + * collection are referred to as a full GC and a zone GC respectively. + * + * It is possible for an incremental collection that started out as a full GC to + * become a zone GC if new zones are created during the course of the + * collection. + * + * Incremental collection + * ---------------------- + * + * For a collection to be carried out incrementally the following conditions + * must be met: + * - the collection must be run by calling js::GCSlice() rather than js::GC() + * - the GC parameter JSGC_INCREMENTAL_GC_ENABLED must be true. + * + * The last condition is an engine-internal mechanism to ensure that incremental + * collection is not carried out without the correct barriers being implemented. + * For more information see 'Incremental marking' below. + * + * If the collection is not incremental, all foreground activity happens inside + * a single call to GC() or GCSlice(). However the collection is not complete + * until the background sweeping activity has finished. + * + * An incremental collection proceeds as a series of slices, interleaved with + * mutator activity, i.e. running JavaScript code. Slices are limited by a time + * budget. The slice finishes as soon as possible after the requested time has + * passed. + * + * Collector states + * ---------------- + * + * The collector proceeds through the following states, the current state being + * held in JSRuntime::gcIncrementalState: + * + * - Prepare - unmarks GC things, discards JIT code and other setup + * - MarkRoots - marks the stack and other roots + * - Mark - incrementally marks reachable things + * - Sweep - sweeps zones in groups and continues marking unswept zones + * - Finalize - performs background finalization, concurrent with mutator + * - Compact - incrementally compacts by zone + * - Decommit - performs background decommit and chunk removal + * + * Roots are marked in the first MarkRoots slice; this is the start of the GC + * proper. The following states can take place over one or more slices. + * + * In other words an incremental collection proceeds like this: + * + * Slice 1: Prepare: Starts background task to unmark GC things + * + * ... JS code runs, background unmarking finishes ... + * + * Slice 2: MarkRoots: Roots are pushed onto the mark stack. + * Mark: The mark stack is processed by popping an element, + * marking it, and pushing its children. + * + * ... JS code runs ... + * + * Slice 3: Mark: More mark stack processing. + * + * ... JS code runs ... + * + * Slice n-1: Mark: More mark stack processing. + * + * ... JS code runs ... + * + * Slice n: Mark: Mark stack is completely drained. + * Sweep: Select first group of zones to sweep and sweep them. + * + * ... JS code runs ... + * + * Slice n+1: Sweep: Mark objects in unswept zones that were newly + * identified as alive (see below). Then sweep more zone + * sweep groups. + * + * ... JS code runs ... + * + * Slice n+2: Sweep: Mark objects in unswept zones that were newly + * identified as alive. Then sweep more zones. + * + * ... JS code runs ... + * + * Slice m: Sweep: Sweeping is finished, and background sweeping + * started on the helper thread. + * + * ... JS code runs, remaining sweeping done on background thread ... + * + * When background sweeping finishes the GC is complete. + * + * Incremental marking + * ------------------- + * + * Incremental collection requires close collaboration with the mutator (i.e., + * JS code) to guarantee correctness. + * + * - During an incremental GC, if a memory location (except a root) is written + * to, then the value it previously held must be marked. Write barriers + * ensure this. + * + * - Any object that is allocated during incremental GC must start out marked. + * + * - Roots are marked in the first slice and hence don't need write barriers. + * Roots are things like the C stack and the VM stack. + * + * The problem that write barriers solve is that between slices the mutator can + * change the object graph. We must ensure that it cannot do this in such a way + * that makes us fail to mark a reachable object (marking an unreachable object + * is tolerable). + * + * We use a snapshot-at-the-beginning algorithm to do this. This means that we + * promise to mark at least everything that is reachable at the beginning of + * collection. To implement it we mark the old contents of every non-root memory + * location written to by the mutator while the collection is in progress, using + * write barriers. This is described in gc/Barrier.h. + * + * Incremental sweeping + * -------------------- + * + * Sweeping is difficult to do incrementally because object finalizers must be + * run at the start of sweeping, before any mutator code runs. The reason is + * that some objects use their finalizers to remove themselves from caches. If + * mutator code was allowed to run after the start of sweeping, it could observe + * the state of the cache and create a new reference to an object that was just + * about to be destroyed. + * + * Sweeping all finalizable objects in one go would introduce long pauses, so + * instead sweeping broken up into groups of zones. Zones which are not yet + * being swept are still marked, so the issue above does not apply. + * + * The order of sweeping is restricted by cross compartment pointers - for + * example say that object |a| from zone A points to object |b| in zone B and + * neither object was marked when we transitioned to the Sweep phase. Imagine we + * sweep B first and then return to the mutator. It's possible that the mutator + * could cause |a| to become alive through a read barrier (perhaps it was a + * shape that was accessed via a shape table). Then we would need to mark |b|, + * which |a| points to, but |b| has already been swept. + * + * So if there is such a pointer then marking of zone B must not finish before + * marking of zone A. Pointers which form a cycle between zones therefore + * restrict those zones to being swept at the same time, and these are found + * using Tarjan's algorithm for finding the strongly connected components of a + * graph. + * + * GC things without finalizers, and things with finalizers that are able to run + * in the background, are swept on the background thread. This accounts for most + * of the sweeping work. + * + * Reset + * ----- + * + * During incremental collection it is possible, although unlikely, for + * conditions to change such that incremental collection is no longer safe. In + * this case, the collection is 'reset' by resetIncrementalGC(). If we are in + * the mark state, this just stops marking, but if we have started sweeping + * already, we continue non-incrementally until we have swept the current sweep + * group. Following a reset, a new collection is started. + * + * Compacting GC + * ------------- + * + * Compacting GC happens at the end of a major GC as part of the last slice. + * There are three parts: + * + * - Arenas are selected for compaction. + * - The contents of those arenas are moved to new arenas. + * - All references to moved things are updated. + * + * Collecting Atoms + * ---------------- + * + * Atoms are collected differently from other GC things. They are contained in + * a special zone and things in other zones may have pointers to them that are + * not recorded in the cross compartment pointer map. Each zone holds a bitmap + * with the atoms it might be keeping alive, and atoms are only collected if + * they are not included in any zone's atom bitmap. See AtomMarking.cpp for how + * this bitmap is managed. + */ + +#include "gc/GC-inl.h" + +#include "mozilla/Range.h" +#include "mozilla/ScopeExit.h" +#include "mozilla/TextUtils.h" +#include "mozilla/TimeStamp.h" + +#include +#include +#include +#include +#include +#include + +#include "jsapi.h" // JS_AbortIfWrongThread +#include "jstypes.h" + +#include "debugger/DebugAPI.h" +#include "gc/ClearEdgesTracer.h" +#include "gc/GCContext.h" +#include "gc/GCInternals.h" +#include "gc/GCLock.h" +#include "gc/GCProbes.h" +#include "gc/Memory.h" +#include "gc/ParallelMarking.h" +#include "gc/ParallelWork.h" +#include "gc/WeakMap.h" +#include "jit/ExecutableAllocator.h" +#include "jit/JitCode.h" +#include "jit/JitRuntime.h" +#include "jit/ProcessExecutableMemory.h" +#include "js/HeapAPI.h" // JS::GCCellPtr +#include "js/Printer.h" +#include "js/SliceBudget.h" +#include "util/DifferentialTesting.h" +#include "vm/BigIntType.h" +#include "vm/EnvironmentObject.h" +#include "vm/GetterSetter.h" +#include "vm/HelperThreadState.h" +#include "vm/JitActivation.h" +#include "vm/JSObject.h" +#include "vm/JSScript.h" +#include "vm/PropMap.h" +#include "vm/Realm.h" +#include "vm/Shape.h" +#include "vm/StringType.h" +#include "vm/SymbolType.h" +#include "vm/Time.h" + +#include "gc/Heap-inl.h" +#include "gc/Nursery-inl.h" +#include "gc/ObjectKind-inl.h" +#include "gc/PrivateIterators-inl.h" +#include "vm/GeckoProfiler-inl.h" +#include "vm/JSContext-inl.h" +#include "vm/Realm-inl.h" +#include "vm/Stack-inl.h" + +using namespace js; +using namespace js::gc; + +using mozilla::MakeScopeExit; +using mozilla::Maybe; +using mozilla::Nothing; +using mozilla::Some; +using mozilla::TimeDuration; +using mozilla::TimeStamp; + +using JS::AutoGCRooter; + +const AllocKind gc::slotsToThingKind[] = { + // clang-format off + /* 0 */ AllocKind::OBJECT0, AllocKind::OBJECT2, AllocKind::OBJECT2, AllocKind::OBJECT4, + /* 4 */ AllocKind::OBJECT4, AllocKind::OBJECT8, AllocKind::OBJECT8, AllocKind::OBJECT8, + /* 8 */ AllocKind::OBJECT8, AllocKind::OBJECT12, AllocKind::OBJECT12, AllocKind::OBJECT12, + /* 12 */ AllocKind::OBJECT12, AllocKind::OBJECT16, AllocKind::OBJECT16, AllocKind::OBJECT16, + /* 16 */ AllocKind::OBJECT16 + // clang-format on +}; + +static_assert(std::size(slotsToThingKind) == SLOTS_TO_THING_KIND_LIMIT, + "We have defined a slot count for each kind."); + +// A table converting an object size in "slots" (increments of +// sizeof(js::Value)) to the total number of bytes in the corresponding +// AllocKind. See gc::slotsToThingKind. This primarily allows wasm jit code to +// remain compliant with the AllocKind system. +// +// To use this table, subtract sizeof(NativeObject) from your desired allocation +// size, divide by sizeof(js::Value) to get the number of "slots", and then +// index into this table. See gc::GetGCObjectKindForBytes. +const constexpr uint32_t gc::slotsToAllocKindBytes[] = { + // These entries correspond exactly to gc::slotsToThingKind. The numeric + // comments therefore indicate the number of slots that the "bytes" would + // correspond to. + // clang-format off + /* 0 */ sizeof(JSObject_Slots0), sizeof(JSObject_Slots2), sizeof(JSObject_Slots2), sizeof(JSObject_Slots4), + /* 4 */ sizeof(JSObject_Slots4), sizeof(JSObject_Slots8), sizeof(JSObject_Slots8), sizeof(JSObject_Slots8), + /* 8 */ sizeof(JSObject_Slots8), sizeof(JSObject_Slots12), sizeof(JSObject_Slots12), sizeof(JSObject_Slots12), + /* 12 */ sizeof(JSObject_Slots12), sizeof(JSObject_Slots16), sizeof(JSObject_Slots16), sizeof(JSObject_Slots16), + /* 16 */ sizeof(JSObject_Slots16) + // clang-format on +}; + +static_assert(std::size(slotsToAllocKindBytes) == SLOTS_TO_THING_KIND_LIMIT); + +MOZ_THREAD_LOCAL(JS::GCContext*) js::TlsGCContext; + +JS::GCContext::GCContext(JSRuntime* runtime) : runtime_(runtime) {} + +JS::GCContext::~GCContext() { + MOZ_ASSERT(!hasJitCodeToPoison()); + MOZ_ASSERT(!isCollecting()); + MOZ_ASSERT(gcUse() == GCUse::None); + MOZ_ASSERT(!gcSweepZone()); + MOZ_ASSERT(!isTouchingGrayThings()); +} + +void JS::GCContext::poisonJitCode() { + if (hasJitCodeToPoison()) { + jit::ExecutableAllocator::poisonCode(runtime(), jitPoisonRanges); + jitPoisonRanges.clearAndFree(); + } +} + +#ifdef DEBUG +void GCRuntime::verifyAllChunks() { + AutoLockGC lock(this); + fullChunks(lock).verifyChunks(); + availableChunks(lock).verifyChunks(); + emptyChunks(lock).verifyChunks(); +} +#endif + +void GCRuntime::setMinEmptyChunkCount(uint32_t value, const AutoLockGC& lock) { + minEmptyChunkCount_ = value; + if (minEmptyChunkCount_ > maxEmptyChunkCount_) { + maxEmptyChunkCount_ = minEmptyChunkCount_; + } + MOZ_ASSERT(maxEmptyChunkCount_ >= minEmptyChunkCount_); +} + +void GCRuntime::setMaxEmptyChunkCount(uint32_t value, const AutoLockGC& lock) { + maxEmptyChunkCount_ = value; + if (minEmptyChunkCount_ > maxEmptyChunkCount_) { + minEmptyChunkCount_ = maxEmptyChunkCount_; + } + MOZ_ASSERT(maxEmptyChunkCount_ >= minEmptyChunkCount_); +} + +inline bool GCRuntime::tooManyEmptyChunks(const AutoLockGC& lock) { + return emptyChunks(lock).count() > minEmptyChunkCount(lock); +} + +ChunkPool GCRuntime::expireEmptyChunkPool(const AutoLockGC& lock) { + MOZ_ASSERT(emptyChunks(lock).verify()); + MOZ_ASSERT(minEmptyChunkCount(lock) <= maxEmptyChunkCount(lock)); + + ChunkPool expired; + while (tooManyEmptyChunks(lock)) { + TenuredChunk* chunk = emptyChunks(lock).pop(); + prepareToFreeChunk(chunk->info); + expired.push(chunk); + } + + MOZ_ASSERT(expired.verify()); + MOZ_ASSERT(emptyChunks(lock).verify()); + MOZ_ASSERT(emptyChunks(lock).count() <= maxEmptyChunkCount(lock)); + MOZ_ASSERT(emptyChunks(lock).count() <= minEmptyChunkCount(lock)); + return expired; +} + +static void FreeChunkPool(ChunkPool& pool) { + for (ChunkPool::Iter iter(pool); !iter.done();) { + TenuredChunk* chunk = iter.get(); + iter.next(); + pool.remove(chunk); + MOZ_ASSERT(chunk->unused()); + UnmapPages(static_cast(chunk), ChunkSize); + } + MOZ_ASSERT(pool.count() == 0); +} + +void GCRuntime::freeEmptyChunks(const AutoLockGC& lock) { + FreeChunkPool(emptyChunks(lock)); +} + +inline void GCRuntime::prepareToFreeChunk(TenuredChunkInfo& info) { + MOZ_ASSERT(numArenasFreeCommitted >= info.numArenasFreeCommitted); + numArenasFreeCommitted -= info.numArenasFreeCommitted; + stats().count(gcstats::COUNT_DESTROY_CHUNK); +#ifdef DEBUG + /* + * Let FreeChunkPool detect a missing prepareToFreeChunk call before it + * frees chunk. + */ + info.numArenasFreeCommitted = 0; +#endif +} + +void GCRuntime::releaseArena(Arena* arena, const AutoLockGC& lock) { + MOZ_ASSERT(arena->allocated()); + MOZ_ASSERT(!arena->onDelayedMarkingList()); + MOZ_ASSERT(TlsGCContext.get()->isFinalizing()); + + arena->zone->gcHeapSize.removeGCArena(heapSize); + arena->release(lock); + arena->chunk()->releaseArena(this, arena, lock); +} + +GCRuntime::GCRuntime(JSRuntime* rt) + : rt(rt), + systemZone(nullptr), + mainThreadContext(rt), + heapState_(JS::HeapState::Idle), + stats_(this), + sweepingTracer(rt), + fullGCRequested(false), + helperThreadRatio(TuningDefaults::HelperThreadRatio), + maxHelperThreads(TuningDefaults::MaxHelperThreads), + helperThreadCount(1), + createBudgetCallback(nullptr), + minEmptyChunkCount_(TuningDefaults::MinEmptyChunkCount), + maxEmptyChunkCount_(TuningDefaults::MaxEmptyChunkCount), + rootsHash(256), + nextCellUniqueId_(LargestTaggedNullCellPointer + + 1), // Ensure disjoint from null tagged pointers. + numArenasFreeCommitted(0), + verifyPreData(nullptr), + lastGCStartTime_(TimeStamp::Now()), + lastGCEndTime_(TimeStamp::Now()), + incrementalGCEnabled(TuningDefaults::IncrementalGCEnabled), + perZoneGCEnabled(TuningDefaults::PerZoneGCEnabled), + numActiveZoneIters(0), + cleanUpEverything(false), + grayBitsValid(true), + majorGCTriggerReason(JS::GCReason::NO_REASON), + minorGCNumber(0), + majorGCNumber(0), + number(0), + sliceNumber(0), + isFull(false), + incrementalState(gc::State::NotActive), + initialState(gc::State::NotActive), + useZeal(false), + lastMarkSlice(false), + safeToYield(true), + markOnBackgroundThreadDuringSweeping(false), + useBackgroundThreads(false), +#ifdef DEBUG + hadShutdownGC(false), +#endif + requestSliceAfterBackgroundTask(false), + lifoBlocksToFree((size_t)JSContext::TEMP_LIFO_ALLOC_PRIMARY_CHUNK_SIZE), + lifoBlocksToFreeAfterMinorGC( + (size_t)JSContext::TEMP_LIFO_ALLOC_PRIMARY_CHUNK_SIZE), + sweepGroupIndex(0), + sweepGroups(nullptr), + currentSweepGroup(nullptr), + sweepZone(nullptr), + abortSweepAfterCurrentGroup(false), + sweepMarkResult(IncrementalProgress::NotFinished), +#ifdef DEBUG + testMarkQueue(rt), +#endif + startedCompacting(false), + zonesCompacted(0), +#ifdef DEBUG + relocatedArenasToRelease(nullptr), +#endif +#ifdef JS_GC_ZEAL + markingValidator(nullptr), +#endif + defaultTimeBudgetMS_(TuningDefaults::DefaultTimeBudgetMS), + incrementalAllowed(true), + compactingEnabled(TuningDefaults::CompactingEnabled), + parallelMarkingEnabled(TuningDefaults::ParallelMarkingEnabled), + rootsRemoved(false), +#ifdef JS_GC_ZEAL + zealModeBits(0), + zealFrequency(0), + nextScheduled(0), + deterministicOnly(false), + zealSliceBudget(0), + selectedForMarking(rt), +#endif + fullCompartmentChecks(false), + gcCallbackDepth(0), + alwaysPreserveCode(false), + lowMemoryState(false), + lock(mutexid::GCLock), + storeBufferLock(mutexid::StoreBuffer), + delayedMarkingLock(mutexid::GCDelayedMarkingLock), + allocTask(this, emptyChunks_.ref()), + unmarkTask(this), + markTask(this), + sweepTask(this), + freeTask(this), + decommitTask(this), + nursery_(this), + storeBuffer_(rt), + lastAllocRateUpdateTime(TimeStamp::Now()) { +} + +using CharRange = mozilla::Range; +using CharRangeVector = Vector; + +static bool SplitStringBy(const CharRange& text, char delimiter, + CharRangeVector* result) { + auto start = text.begin(); + for (auto ptr = start; ptr != text.end(); ptr++) { + if (*ptr == delimiter) { + if (!result->emplaceBack(start, ptr)) { + return false; + } + start = ptr + 1; + } + } + + return result->emplaceBack(start, text.end()); +} + +static bool ParseTimeDuration(const CharRange& text, + TimeDuration* durationOut) { + const char* str = text.begin().get(); + char* end; + long millis = strtol(str, &end, 10); + *durationOut = TimeDuration::FromMilliseconds(double(millis)); + return str != end && end == text.end().get(); +} + +static void PrintProfileHelpAndExit(const char* envName, const char* helpText) { + fprintf(stderr, "%s=N[,(main|all)]\n", envName); + fprintf(stderr, "%s", helpText); + exit(0); +} + +void js::gc::ReadProfileEnv(const char* envName, const char* helpText, + bool* enableOut, bool* workersOut, + TimeDuration* thresholdOut) { + *enableOut = false; + *workersOut = false; + *thresholdOut = TimeDuration::Zero(); + + const char* env = getenv(envName); + if (!env) { + return; + } + + if (strcmp(env, "help") == 0) { + PrintProfileHelpAndExit(envName, helpText); + } + + CharRangeVector parts; + auto text = CharRange(env, strlen(env)); + if (!SplitStringBy(text, ',', &parts)) { + MOZ_CRASH("OOM parsing environment variable"); + } + + if (parts.length() == 0 || parts.length() > 2) { + PrintProfileHelpAndExit(envName, helpText); + } + + *enableOut = true; + + if (!ParseTimeDuration(parts[0], thresholdOut)) { + PrintProfileHelpAndExit(envName, helpText); + } + + if (parts.length() == 2) { + const char* threads = parts[1].begin().get(); + if (strcmp(threads, "all") == 0) { + *workersOut = true; + } else if (strcmp(threads, "main") != 0) { + PrintProfileHelpAndExit(envName, helpText); + } + } +} + +bool js::gc::ShouldPrintProfile(JSRuntime* runtime, bool enable, + bool profileWorkers, TimeDuration threshold, + TimeDuration duration) { + return enable && (runtime->isMainRuntime() || profileWorkers) && + duration >= threshold; +} + +#ifdef JS_GC_ZEAL + +void GCRuntime::getZealBits(uint32_t* zealBits, uint32_t* frequency, + uint32_t* scheduled) { + *zealBits = zealModeBits; + *frequency = zealFrequency; + *scheduled = nextScheduled; +} + +const char gc::ZealModeHelpText[] = + " Specifies how zealous the garbage collector should be. Some of these " + "modes can\n" + " be set simultaneously, by passing multiple level options, e.g. \"2;4\" " + "will activate\n" + " both modes 2 and 4. Modes can be specified by name or number.\n" + " \n" + " Values:\n" + " 0: (None) Normal amount of collection (resets all modes)\n" + " 1: (RootsChange) Collect when roots are added or removed\n" + " 2: (Alloc) Collect when every N allocations (default: 100)\n" + " 4: (VerifierPre) Verify pre write barriers between instructions\n" + " 6: (YieldBeforeRootMarking) Incremental GC in two slices that yields " + "before root marking\n" + " 7: (GenerationalGC) Collect the nursery every N nursery allocations\n" + " 8: (YieldBeforeMarking) Incremental GC in two slices that yields " + "between\n" + " the root marking and marking phases\n" + " 9: (YieldBeforeSweeping) Incremental GC in two slices that yields " + "between\n" + " the marking and sweeping phases\n" + " 10: (IncrementalMultipleSlices) Incremental GC in many slices\n" + " 11: (IncrementalMarkingValidator) Verify incremental marking\n" + " 12: (ElementsBarrier) Use the individual element post-write barrier\n" + " regardless of elements size\n" + " 13: (CheckHashTablesOnMinorGC) Check internal hashtables on minor GC\n" + " 14: (Compact) Perform a shrinking collection every N allocations\n" + " 15: (CheckHeapAfterGC) Walk the heap to check its integrity after " + "every GC\n" + " 17: (YieldBeforeSweepingAtoms) Incremental GC in two slices that " + "yields\n" + " before sweeping the atoms table\n" + " 18: (CheckGrayMarking) Check gray marking invariants after every GC\n" + " 19: (YieldBeforeSweepingCaches) Incremental GC in two slices that " + "yields\n" + " before sweeping weak caches\n" + " 21: (YieldBeforeSweepingObjects) Incremental GC in two slices that " + "yields\n" + " before sweeping foreground finalized objects\n" + " 22: (YieldBeforeSweepingNonObjects) Incremental GC in two slices that " + "yields\n" + " before sweeping non-object GC things\n" + " 23: (YieldBeforeSweepingPropMapTrees) Incremental GC in two slices " + "that " + "yields\n" + " before sweeping shape trees\n" + " 24: (CheckWeakMapMarking) Check weak map marking invariants after " + "every GC\n" + " 25: (YieldWhileGrayMarking) Incremental GC in two slices that yields\n" + " during gray marking\n"; + +// The set of zeal modes that control incremental slices. These modes are +// mutually exclusive. +static const mozilla::EnumSet IncrementalSliceZealModes = { + ZealMode::YieldBeforeRootMarking, + ZealMode::YieldBeforeMarking, + ZealMode::YieldBeforeSweeping, + ZealMode::IncrementalMultipleSlices, + ZealMode::YieldBeforeSweepingAtoms, + ZealMode::YieldBeforeSweepingCaches, + ZealMode::YieldBeforeSweepingObjects, + ZealMode::YieldBeforeSweepingNonObjects, + ZealMode::YieldBeforeSweepingPropMapTrees}; + +void GCRuntime::setZeal(uint8_t zeal, uint32_t frequency) { + MOZ_ASSERT(zeal <= unsigned(ZealMode::Limit)); + + if (verifyPreData) { + VerifyBarriers(rt, PreBarrierVerifier); + } + + if (zeal == 0) { + if (hasZealMode(ZealMode::GenerationalGC)) { + evictNursery(JS::GCReason::DEBUG_GC); + nursery().leaveZealMode(); + } + + if (isIncrementalGCInProgress()) { + finishGC(JS::GCReason::DEBUG_GC); + } + } + + ZealMode zealMode = ZealMode(zeal); + if (zealMode == ZealMode::GenerationalGC) { + evictNursery(JS::GCReason::DEBUG_GC); + nursery().enterZealMode(); + } + + // Some modes are mutually exclusive. If we're setting one of those, we + // first reset all of them. + if (IncrementalSliceZealModes.contains(zealMode)) { + for (auto mode : IncrementalSliceZealModes) { + clearZealMode(mode); + } + } + + bool schedule = zealMode >= ZealMode::Alloc; + if (zeal != 0) { + zealModeBits |= 1 << unsigned(zeal); + } else { + zealModeBits = 0; + } + zealFrequency = frequency; + nextScheduled = schedule ? frequency : 0; +} + +void GCRuntime::unsetZeal(uint8_t zeal) { + MOZ_ASSERT(zeal <= unsigned(ZealMode::Limit)); + ZealMode zealMode = ZealMode(zeal); + + if (!hasZealMode(zealMode)) { + return; + } + + if (verifyPreData) { + VerifyBarriers(rt, PreBarrierVerifier); + } + + if (zealMode == ZealMode::GenerationalGC) { + evictNursery(JS::GCReason::DEBUG_GC); + nursery().leaveZealMode(); + } + + clearZealMode(zealMode); + + if (zealModeBits == 0) { + if (isIncrementalGCInProgress()) { + finishGC(JS::GCReason::DEBUG_GC); + } + + zealFrequency = 0; + nextScheduled = 0; + } +} + +void GCRuntime::setNextScheduled(uint32_t count) { nextScheduled = count; } + +static bool ParseZealModeName(const CharRange& text, uint32_t* modeOut) { + struct ModeInfo { + const char* name; + size_t length; + uint32_t value; + }; + + static const ModeInfo zealModes[] = {{"None", 0}, +# define ZEAL_MODE(name, value) {#name, strlen(#name), value}, + JS_FOR_EACH_ZEAL_MODE(ZEAL_MODE) +# undef ZEAL_MODE + }; + + for (auto mode : zealModes) { + if (text.length() == mode.length && + memcmp(text.begin().get(), mode.name, mode.length) == 0) { + *modeOut = mode.value; + return true; + } + } + + return false; +} + +static bool ParseZealModeNumericParam(const CharRange& text, + uint32_t* paramOut) { + if (text.length() == 0) { + return false; + } + + for (auto c : text) { + if (!mozilla::IsAsciiDigit(c)) { + return false; + } + } + + *paramOut = atoi(text.begin().get()); + return true; +} + +static bool PrintZealHelpAndFail() { + fprintf(stderr, "Format: JS_GC_ZEAL=level(;level)*[,N]\n"); + fputs(ZealModeHelpText, stderr); + return false; +} + +bool GCRuntime::parseAndSetZeal(const char* str) { + // Set the zeal mode from a string consisting of one or more mode specifiers + // separated by ';', optionally followed by a ',' and the trigger frequency. + // The mode specifiers can by a mode name or its number. + + auto text = CharRange(str, strlen(str)); + + CharRangeVector parts; + if (!SplitStringBy(text, ',', &parts)) { + return false; + } + + if (parts.length() == 0 || parts.length() > 2) { + return PrintZealHelpAndFail(); + } + + uint32_t frequency = JS_DEFAULT_ZEAL_FREQ; + if (parts.length() == 2 && !ParseZealModeNumericParam(parts[1], &frequency)) { + return PrintZealHelpAndFail(); + } + + CharRangeVector modes; + if (!SplitStringBy(parts[0], ';', &modes)) { + return false; + } + + for (const auto& descr : modes) { + uint32_t mode; + if (!ParseZealModeName(descr, &mode) && + !(ParseZealModeNumericParam(descr, &mode) && + mode <= unsigned(ZealMode::Limit))) { + return PrintZealHelpAndFail(); + } + + setZeal(mode, frequency); + } + + return true; +} + +const char* js::gc::AllocKindName(AllocKind kind) { + static const char* const names[] = { +# define EXPAND_THING_NAME(allocKind, _1, _2, _3, _4, _5, _6) #allocKind, + FOR_EACH_ALLOCKIND(EXPAND_THING_NAME) +# undef EXPAND_THING_NAME + }; + static_assert(std::size(names) == AllocKindCount, + "names array should have an entry for every AllocKind"); + + size_t i = size_t(kind); + MOZ_ASSERT(i < std::size(names)); + return names[i]; +} + +void js::gc::DumpArenaInfo() { + fprintf(stderr, "Arena header size: %zu\n\n", ArenaHeaderSize); + + fprintf(stderr, "GC thing kinds:\n"); + fprintf(stderr, "%25s %8s %8s %8s\n", + "AllocKind:", "Size:", "Count:", "Padding:"); + for (auto kind : AllAllocKinds()) { + fprintf(stderr, "%25s %8zu %8zu %8zu\n", AllocKindName(kind), + Arena::thingSize(kind), Arena::thingsPerArena(kind), + Arena::firstThingOffset(kind) - ArenaHeaderSize); + } +} + +#endif // JS_GC_ZEAL + +bool GCRuntime::init(uint32_t maxbytes) { + MOZ_ASSERT(!wasInitialized()); + + MOZ_ASSERT(SystemPageSize()); + Arena::checkLookupTables(); + + if (!TlsGCContext.init()) { + return false; + } + TlsGCContext.set(&mainThreadContext.ref()); + + updateHelperThreadCount(); + +#ifdef JS_GC_ZEAL + const char* size = getenv("JSGC_MARK_STACK_LIMIT"); + if (size) { + maybeMarkStackLimit = atoi(size); + } +#endif + + if (!updateMarkersVector()) { + return false; + } + + { + AutoLockGCBgAlloc lock(this); + + MOZ_ALWAYS_TRUE(tunables.setParameter(JSGC_MAX_BYTES, maxbytes)); + + if (!nursery().init(lock)) { + return false; + } + } + +#ifdef JS_GC_ZEAL + const char* zealSpec = getenv("JS_GC_ZEAL"); + if (zealSpec && zealSpec[0] && !parseAndSetZeal(zealSpec)) { + return false; + } +#endif + + for (auto& marker : markers) { + if (!marker->init()) { + return false; + } + } + + if (!initSweepActions()) { + return false; + } + + UniquePtr zone = MakeUnique(rt, Zone::AtomsZone); + if (!zone || !zone->init()) { + return false; + } + + // The atoms zone is stored as the first element of the zones vector. + MOZ_ASSERT(zone->isAtomsZone()); + MOZ_ASSERT(zones().empty()); + MOZ_ALWAYS_TRUE(zones().reserve(1)); // ZonesVector has inline capacity 4. + zones().infallibleAppend(zone.release()); + + gcprobes::Init(this); + + initialized = true; + return true; +} + +void GCRuntime::finish() { + MOZ_ASSERT(inPageLoadCount == 0); + MOZ_ASSERT(!sharedAtomsZone_); + + // Wait for nursery background free to end and disable it to release memory. + if (nursery().isEnabled()) { + nursery().disable(); + } + + // Wait until the background finalization and allocation stops and the + // helper thread shuts down before we forcefully release any remaining GC + // memory. + sweepTask.join(); + markTask.join(); + freeTask.join(); + allocTask.cancelAndWait(); + decommitTask.cancelAndWait(); +#ifdef DEBUG + { + MOZ_ASSERT(dispatchedParallelTasks == 0); + AutoLockHelperThreadState lock; + MOZ_ASSERT(queuedParallelTasks.ref().isEmpty(lock)); + } +#endif + +#ifdef JS_GC_ZEAL + // Free memory associated with GC verification. + finishVerifier(); +#endif + + // Delete all remaining zones. + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + AutoSetThreadIsSweeping threadIsSweeping(rt->gcContext(), zone); + for (CompartmentsInZoneIter comp(zone); !comp.done(); comp.next()) { + for (RealmsInCompartmentIter realm(comp); !realm.done(); realm.next()) { + js_delete(realm.get()); + } + comp->realms().clear(); + js_delete(comp.get()); + } + zone->compartments().clear(); + js_delete(zone.get()); + } + + zones().clear(); + + FreeChunkPool(fullChunks_.ref()); + FreeChunkPool(availableChunks_.ref()); + FreeChunkPool(emptyChunks_.ref()); + + TlsGCContext.set(nullptr); + + gcprobes::Finish(this); + + nursery().printTotalProfileTimes(); + stats().printTotalProfileTimes(); +} + +bool GCRuntime::freezeSharedAtomsZone() { + // This is called just after permanent atoms and well-known symbols have been + // created. At this point all existing atoms and symbols are permanent. + // + // This method makes the current atoms zone into a shared atoms zone and + // removes it from the zones list. Everything in it is marked black. A new + // empty atoms zone is created, where all atoms local to this runtime will + // live. + // + // The shared atoms zone will not be collected until shutdown when it is + // returned to the zone list by restoreSharedAtomsZone(). + + MOZ_ASSERT(rt->isMainRuntime()); + MOZ_ASSERT(!sharedAtomsZone_); + MOZ_ASSERT(zones().length() == 1); + MOZ_ASSERT(atomsZone()); + MOZ_ASSERT(!atomsZone()->wasGCStarted()); + MOZ_ASSERT(!atomsZone()->needsIncrementalBarrier()); + + AutoAssertEmptyNursery nurseryIsEmpty(rt->mainContextFromOwnThread()); + + atomsZone()->arenas.clearFreeLists(); + + for (auto kind : AllAllocKinds()) { + for (auto thing = + atomsZone()->cellIterUnsafe(kind, nurseryIsEmpty); + !thing.done(); thing.next()) { + TenuredCell* cell = thing.getCell(); + MOZ_ASSERT((cell->is() && + cell->as()->isPermanentAndMayBeShared()) || + (cell->is() && + cell->as()->isPermanentAndMayBeShared())); + cell->markBlack(); + } + } + + sharedAtomsZone_ = atomsZone(); + zones().clear(); + + UniquePtr zone = MakeUnique(rt, Zone::AtomsZone); + if (!zone || !zone->init()) { + return false; + } + + MOZ_ASSERT(zone->isAtomsZone()); + zones().infallibleAppend(zone.release()); + + return true; +} + +void GCRuntime::restoreSharedAtomsZone() { + // Return the shared atoms zone to the zone list. This allows the contents of + // the shared atoms zone to be collected when the parent runtime is shut down. + + if (!sharedAtomsZone_) { + return; + } + + MOZ_ASSERT(rt->isMainRuntime()); + MOZ_ASSERT(rt->childRuntimeCount == 0); + + AutoEnterOOMUnsafeRegion oomUnsafe; + if (!zones().append(sharedAtomsZone_)) { + oomUnsafe.crash("restoreSharedAtomsZone"); + } + + sharedAtomsZone_ = nullptr; +} + +bool GCRuntime::setParameter(JSContext* cx, JSGCParamKey key, uint32_t value) { + MOZ_ASSERT(CurrentThreadCanAccessRuntime(rt)); + + AutoStopVerifyingBarriers pauseVerification(rt, false); + FinishGC(cx); + waitBackgroundSweepEnd(); + + AutoLockGC lock(this); + return setParameter(key, value, lock); +} + +static bool IsGCThreadParameter(JSGCParamKey key) { + return key == JSGC_HELPER_THREAD_RATIO || key == JSGC_MAX_HELPER_THREADS || + key == JSGC_MARKING_THREAD_COUNT; +} + +bool GCRuntime::setParameter(JSGCParamKey key, uint32_t value, + AutoLockGC& lock) { + switch (key) { + case JSGC_SLICE_TIME_BUDGET_MS: + defaultTimeBudgetMS_ = value; + break; + case JSGC_INCREMENTAL_GC_ENABLED: + setIncrementalGCEnabled(value != 0); + break; + case JSGC_PER_ZONE_GC_ENABLED: + perZoneGCEnabled = value != 0; + break; + case JSGC_COMPACTING_ENABLED: + compactingEnabled = value != 0; + break; + case JSGC_PARALLEL_MARKING_ENABLED: + // Not supported on workers. + parallelMarkingEnabled = rt->isMainRuntime() && value != 0; + return initOrDisableParallelMarking(); + case JSGC_INCREMENTAL_WEAKMAP_ENABLED: + for (auto& marker : markers) { + marker->incrementalWeakMapMarkingEnabled = value != 0; + } + break; + case JSGC_MIN_EMPTY_CHUNK_COUNT: + setMinEmptyChunkCount(value, lock); + break; + case JSGC_MAX_EMPTY_CHUNK_COUNT: + setMaxEmptyChunkCount(value, lock); + break; + default: + if (IsGCThreadParameter(key)) { + return setThreadParameter(key, value, lock); + } + + if (!tunables.setParameter(key, value)) { + return false; + } + updateAllGCStartThresholds(); + } + + return true; +} + +bool GCRuntime::setThreadParameter(JSGCParamKey key, uint32_t value, + AutoLockGC& lock) { + if (rt->parentRuntime) { + // Don't allow these to be set for worker runtimes. + return false; + } + + switch (key) { + case JSGC_HELPER_THREAD_RATIO: + if (value == 0) { + return false; + } + helperThreadRatio = double(value) / 100.0; + break; + case JSGC_MAX_HELPER_THREADS: + if (value == 0) { + return false; + } + maxHelperThreads = value; + break; + case JSGC_MARKING_THREAD_COUNT: + markingThreadCount = std::min(size_t(value), MaxParallelWorkers); + break; + default: + MOZ_CRASH("Unexpected parameter key"); + } + + updateHelperThreadCount(); + initOrDisableParallelMarking(); + + return true; +} + +void GCRuntime::resetParameter(JSContext* cx, JSGCParamKey key) { + MOZ_ASSERT(CurrentThreadCanAccessRuntime(rt)); + + AutoStopVerifyingBarriers pauseVerification(rt, false); + FinishGC(cx); + waitBackgroundSweepEnd(); + + AutoLockGC lock(this); + resetParameter(key, lock); +} + +void GCRuntime::resetParameter(JSGCParamKey key, AutoLockGC& lock) { + switch (key) { + case JSGC_SLICE_TIME_BUDGET_MS: + defaultTimeBudgetMS_ = TuningDefaults::DefaultTimeBudgetMS; + break; + case JSGC_INCREMENTAL_GC_ENABLED: + setIncrementalGCEnabled(TuningDefaults::IncrementalGCEnabled); + break; + case JSGC_PER_ZONE_GC_ENABLED: + perZoneGCEnabled = TuningDefaults::PerZoneGCEnabled; + break; + case JSGC_COMPACTING_ENABLED: + compactingEnabled = TuningDefaults::CompactingEnabled; + break; + case JSGC_PARALLEL_MARKING_ENABLED: + parallelMarkingEnabled = TuningDefaults::ParallelMarkingEnabled; + initOrDisableParallelMarking(); + break; + case JSGC_INCREMENTAL_WEAKMAP_ENABLED: + for (auto& marker : markers) { + marker->incrementalWeakMapMarkingEnabled = + TuningDefaults::IncrementalWeakMapMarkingEnabled; + } + break; + case JSGC_MIN_EMPTY_CHUNK_COUNT: + setMinEmptyChunkCount(TuningDefaults::MinEmptyChunkCount, lock); + break; + case JSGC_MAX_EMPTY_CHUNK_COUNT: + setMaxEmptyChunkCount(TuningDefaults::MaxEmptyChunkCount, lock); + break; + default: + if (IsGCThreadParameter(key)) { + resetThreadParameter(key, lock); + return; + } + + tunables.resetParameter(key); + updateAllGCStartThresholds(); + } +} + +void GCRuntime::resetThreadParameter(JSGCParamKey key, AutoLockGC& lock) { + if (rt->parentRuntime) { + return; + } + + switch (key) { + case JSGC_HELPER_THREAD_RATIO: + helperThreadRatio = TuningDefaults::HelperThreadRatio; + break; + case JSGC_MAX_HELPER_THREADS: + maxHelperThreads = TuningDefaults::MaxHelperThreads; + break; + case JSGC_MARKING_THREAD_COUNT: + markingThreadCount = 0; + break; + default: + MOZ_CRASH("Unexpected parameter key"); + } + + updateHelperThreadCount(); + initOrDisableParallelMarking(); +} + +uint32_t GCRuntime::getParameter(JSGCParamKey key) { + MOZ_ASSERT(CurrentThreadCanAccessRuntime(rt)); + AutoLockGC lock(this); + return getParameter(key, lock); +} + +uint32_t GCRuntime::getParameter(JSGCParamKey key, const AutoLockGC& lock) { + switch (key) { + case JSGC_BYTES: + return uint32_t(heapSize.bytes()); + case JSGC_NURSERY_BYTES: + return nursery().capacity(); + case JSGC_NUMBER: + return uint32_t(number); + case JSGC_MAJOR_GC_NUMBER: + return uint32_t(majorGCNumber); + case JSGC_MINOR_GC_NUMBER: + return uint32_t(minorGCNumber); + case JSGC_INCREMENTAL_GC_ENABLED: + return incrementalGCEnabled; + case JSGC_PER_ZONE_GC_ENABLED: + return perZoneGCEnabled; + case JSGC_UNUSED_CHUNKS: + return uint32_t(emptyChunks(lock).count()); + case JSGC_TOTAL_CHUNKS: + return uint32_t(fullChunks(lock).count() + availableChunks(lock).count() + + emptyChunks(lock).count()); + case JSGC_SLICE_TIME_BUDGET_MS: + MOZ_RELEASE_ASSERT(defaultTimeBudgetMS_ >= 0); + MOZ_RELEASE_ASSERT(defaultTimeBudgetMS_ <= UINT32_MAX); + return uint32_t(defaultTimeBudgetMS_); + case JSGC_MIN_EMPTY_CHUNK_COUNT: + return minEmptyChunkCount(lock); + case JSGC_MAX_EMPTY_CHUNK_COUNT: + return maxEmptyChunkCount(lock); + case JSGC_COMPACTING_ENABLED: + return compactingEnabled; + case JSGC_PARALLEL_MARKING_ENABLED: + return parallelMarkingEnabled; + case JSGC_INCREMENTAL_WEAKMAP_ENABLED: + return marker().incrementalWeakMapMarkingEnabled; + case JSGC_CHUNK_BYTES: + return ChunkSize; + case JSGC_HELPER_THREAD_RATIO: + MOZ_ASSERT(helperThreadRatio > 0.0); + return uint32_t(helperThreadRatio * 100.0); + case JSGC_MAX_HELPER_THREADS: + MOZ_ASSERT(maxHelperThreads <= UINT32_MAX); + return maxHelperThreads; + case JSGC_HELPER_THREAD_COUNT: + return helperThreadCount; + case JSGC_MARKING_THREAD_COUNT: + return markingThreadCount; + case JSGC_SYSTEM_PAGE_SIZE_KB: + return SystemPageSize() / 1024; + default: + return tunables.getParameter(key); + } +} + +#ifdef JS_GC_ZEAL +void GCRuntime::setMarkStackLimit(size_t limit, AutoLockGC& lock) { + MOZ_ASSERT(!JS::RuntimeHeapIsBusy()); + + maybeMarkStackLimit = limit; + + AutoUnlockGC unlock(lock); + AutoStopVerifyingBarriers pauseVerification(rt, false); + for (auto& marker : markers) { + marker->setMaxCapacity(limit); + } +} +#endif + +void GCRuntime::setIncrementalGCEnabled(bool enabled) { + incrementalGCEnabled = enabled; +} + +void GCRuntime::updateHelperThreadCount() { + if (!CanUseExtraThreads()) { + // startTask will run the work on the main thread if the count is 1. + MOZ_ASSERT(helperThreadCount == 1); + markingThreadCount = 1; + + AutoLockHelperThreadState lock; + maxParallelThreads = 1; + return; + } + + // Number of extra threads required during parallel marking to ensure we can + // start the necessary marking tasks. Background free and background + // allocation may already be running and we want to avoid these tasks blocking + // marking. In real configurations there will be enough threads that this + // won't affect anything. + static constexpr size_t SpareThreadsDuringParallelMarking = 2; + + // Calculate the target thread count for GC parallel tasks. + size_t cpuCount = GetHelperThreadCPUCount(); + helperThreadCount = + std::clamp(size_t(double(cpuCount) * helperThreadRatio.ref()), size_t(1), + maxHelperThreads.ref()); + + // Calculate the overall target thread count taking into account the separate + // parameter for parallel marking threads. Add spare threads to avoid blocking + // parallel marking when there is other GC work happening. + size_t targetCount = + std::max(helperThreadCount.ref(), + markingThreadCount.ref() + SpareThreadsDuringParallelMarking); + + // Attempt to create extra threads if possible. This is not supported when + // using an external thread pool. + AutoLockHelperThreadState lock; + (void)HelperThreadState().ensureThreadCount(targetCount, lock); + + // Limit all thread counts based on the number of threads available, which may + // be fewer than requested. + size_t availableThreadCount = GetHelperThreadCount(); + MOZ_ASSERT(availableThreadCount != 0); + targetCount = std::min(targetCount, availableThreadCount); + helperThreadCount = std::min(helperThreadCount.ref(), availableThreadCount); + markingThreadCount = + std::min(markingThreadCount.ref(), + availableThreadCount - SpareThreadsDuringParallelMarking); + + // Update the maximum number of threads that will be used for GC work. + maxParallelThreads = targetCount; +} + +size_t GCRuntime::markingWorkerCount() const { + if (!CanUseExtraThreads() || !parallelMarkingEnabled) { + return 1; + } + + if (markingThreadCount) { + return markingThreadCount; + } + + // Limit parallel marking to use at most two threads initially. + return 2; +} + +#ifdef DEBUG +void GCRuntime::assertNoMarkingWork() const { + for (const auto& marker : markers) { + MOZ_ASSERT(marker->isDrained()); + } + MOZ_ASSERT(!hasDelayedMarking()); +} +#endif + +bool GCRuntime::initOrDisableParallelMarking() { + // Attempt to initialize parallel marking state or disable it on failure. + + MOZ_ASSERT(markers.length() != 0); + + if (!updateMarkersVector()) { + parallelMarkingEnabled = false; + return false; + } + + return true; +} + +size_t GCRuntime::getMaxParallelThreads() const { + AutoLockHelperThreadState lock; + return maxParallelThreads.ref(); +} + +bool GCRuntime::updateMarkersVector() { + MOZ_ASSERT(helperThreadCount >= 1, + "There must always be at least one mark task"); + MOZ_ASSERT(CurrentThreadCanAccessRuntime(rt)); + assertNoMarkingWork(); + + // Limit worker count to number of GC parallel tasks that can run + // concurrently, otherwise one thread can deadlock waiting on another. + size_t targetCount = std::min(markingWorkerCount(), getMaxParallelThreads()); + + if (markers.length() > targetCount) { + return markers.resize(targetCount); + } + + while (markers.length() < targetCount) { + auto marker = MakeUnique(rt); + if (!marker) { + return false; + } + +#ifdef JS_GC_ZEAL + if (maybeMarkStackLimit) { + marker->setMaxCapacity(maybeMarkStackLimit); + } +#endif + + if (!marker->init()) { + return false; + } + + if (!markers.emplaceBack(std::move(marker))) { + return false; + } + } + + return true; +} + +template +static bool EraseCallback(CallbackVector& vector, F callback) { + for (Callback* p = vector.begin(); p != vector.end(); p++) { + if (p->op == callback) { + vector.erase(p); + return true; + } + } + + return false; +} + +template +static bool EraseCallback(CallbackVector& vector, F callback, void* data) { + for (Callback* p = vector.begin(); p != vector.end(); p++) { + if (p->op == callback && p->data == data) { + vector.erase(p); + return true; + } + } + + return false; +} + +bool GCRuntime::addBlackRootsTracer(JSTraceDataOp traceOp, void* data) { + AssertHeapIsIdle(); + return blackRootTracers.ref().append(Callback(traceOp, data)); +} + +void GCRuntime::removeBlackRootsTracer(JSTraceDataOp traceOp, void* data) { + // Can be called from finalizers + MOZ_ALWAYS_TRUE(EraseCallback(blackRootTracers.ref(), traceOp)); +} + +void GCRuntime::setGrayRootsTracer(JSGrayRootsTracer traceOp, void* data) { + AssertHeapIsIdle(); + grayRootTracer.ref() = {traceOp, data}; +} + +void GCRuntime::clearBlackAndGrayRootTracers() { + MOZ_ASSERT(rt->isBeingDestroyed()); + blackRootTracers.ref().clear(); + setGrayRootsTracer(nullptr, nullptr); +} + +void GCRuntime::setGCCallback(JSGCCallback callback, void* data) { + gcCallback.ref() = {callback, data}; +} + +void GCRuntime::callGCCallback(JSGCStatus status, JS::GCReason reason) const { + const auto& callback = gcCallback.ref(); + MOZ_ASSERT(callback.op); + callback.op(rt->mainContextFromOwnThread(), status, reason, callback.data); +} + +void GCRuntime::setObjectsTenuredCallback(JSObjectsTenuredCallback callback, + void* data) { + tenuredCallback.ref() = {callback, data}; +} + +void GCRuntime::callObjectsTenuredCallback() { + JS::AutoSuppressGCAnalysis nogc; + const auto& callback = tenuredCallback.ref(); + if (callback.op) { + callback.op(rt->mainContextFromOwnThread(), callback.data); + } +} + +bool GCRuntime::addFinalizeCallback(JSFinalizeCallback callback, void* data) { + return finalizeCallbacks.ref().append( + Callback(callback, data)); +} + +void GCRuntime::removeFinalizeCallback(JSFinalizeCallback callback) { + MOZ_ALWAYS_TRUE(EraseCallback(finalizeCallbacks.ref(), callback)); +} + +void GCRuntime::callFinalizeCallbacks(JS::GCContext* gcx, + JSFinalizeStatus status) const { + for (const auto& p : finalizeCallbacks.ref()) { + p.op(gcx, status, p.data); + } +} + +void GCRuntime::setHostCleanupFinalizationRegistryCallback( + JSHostCleanupFinalizationRegistryCallback callback, void* data) { + hostCleanupFinalizationRegistryCallback.ref() = {callback, data}; +} + +void GCRuntime::callHostCleanupFinalizationRegistryCallback( + JSFunction* doCleanup, GlobalObject* incumbentGlobal) { + JS::AutoSuppressGCAnalysis nogc; + const auto& callback = hostCleanupFinalizationRegistryCallback.ref(); + if (callback.op) { + callback.op(doCleanup, incumbentGlobal, callback.data); + } +} + +bool GCRuntime::addWeakPointerZonesCallback(JSWeakPointerZonesCallback callback, + void* data) { + return updateWeakPointerZonesCallbacks.ref().append( + Callback(callback, data)); +} + +void GCRuntime::removeWeakPointerZonesCallback( + JSWeakPointerZonesCallback callback) { + MOZ_ALWAYS_TRUE( + EraseCallback(updateWeakPointerZonesCallbacks.ref(), callback)); +} + +void GCRuntime::callWeakPointerZonesCallbacks(JSTracer* trc) const { + for (auto const& p : updateWeakPointerZonesCallbacks.ref()) { + p.op(trc, p.data); + } +} + +bool GCRuntime::addWeakPointerCompartmentCallback( + JSWeakPointerCompartmentCallback callback, void* data) { + return updateWeakPointerCompartmentCallbacks.ref().append( + Callback(callback, data)); +} + +void GCRuntime::removeWeakPointerCompartmentCallback( + JSWeakPointerCompartmentCallback callback) { + MOZ_ALWAYS_TRUE( + EraseCallback(updateWeakPointerCompartmentCallbacks.ref(), callback)); +} + +void GCRuntime::callWeakPointerCompartmentCallbacks( + JSTracer* trc, JS::Compartment* comp) const { + for (auto const& p : updateWeakPointerCompartmentCallbacks.ref()) { + p.op(trc, comp, p.data); + } +} + +JS::GCSliceCallback GCRuntime::setSliceCallback(JS::GCSliceCallback callback) { + return stats().setSliceCallback(callback); +} + +bool GCRuntime::addNurseryCollectionCallback( + JS::GCNurseryCollectionCallback callback, void* data) { + return nurseryCollectionCallbacks.ref().append( + Callback(callback, data)); +} + +void GCRuntime::removeNurseryCollectionCallback( + JS::GCNurseryCollectionCallback callback, void* data) { + MOZ_ALWAYS_TRUE( + EraseCallback(nurseryCollectionCallbacks.ref(), callback, data)); +} + +void GCRuntime::callNurseryCollectionCallbacks(JS::GCNurseryProgress progress, + JS::GCReason reason) { + for (auto const& p : nurseryCollectionCallbacks.ref()) { + p.op(rt->mainContextFromOwnThread(), progress, reason, p.data); + } +} + +JS::DoCycleCollectionCallback GCRuntime::setDoCycleCollectionCallback( + JS::DoCycleCollectionCallback callback) { + const auto prior = gcDoCycleCollectionCallback.ref(); + gcDoCycleCollectionCallback.ref() = {callback, nullptr}; + return prior.op; +} + +void GCRuntime::callDoCycleCollectionCallback(JSContext* cx) { + const auto& callback = gcDoCycleCollectionCallback.ref(); + if (callback.op) { + callback.op(cx); + } +} + +bool GCRuntime::addRoot(Value* vp, const char* name) { + /* + * Sometimes Firefox will hold weak references to objects and then convert + * them to strong references by calling AddRoot (e.g., via PreserveWrapper, + * or ModifyBusyCount in workers). We need a read barrier to cover these + * cases. + */ + MOZ_ASSERT(vp); + Value value = *vp; + if (value.isGCThing()) { + ValuePreWriteBarrier(value); + } + + return rootsHash.ref().put(vp, name); +} + +void GCRuntime::removeRoot(Value* vp) { + rootsHash.ref().remove(vp); + notifyRootsRemoved(); +} + +/* Compacting GC */ + +bool js::gc::IsCurrentlyAnimating(const TimeStamp& lastAnimationTime, + const TimeStamp& currentTime) { + // Assume that we're currently animating if js::NotifyAnimationActivity has + // been called in the last second. + static const auto oneSecond = TimeDuration::FromSeconds(1); + return !lastAnimationTime.IsNull() && + currentTime < (lastAnimationTime + oneSecond); +} + +static bool DiscardedCodeRecently(Zone* zone, const TimeStamp& currentTime) { + static const auto thirtySeconds = TimeDuration::FromSeconds(30); + return !zone->lastDiscardedCodeTime().IsNull() && + currentTime < (zone->lastDiscardedCodeTime() + thirtySeconds); +} + +bool GCRuntime::shouldCompact() { + // Compact on shrinking GC if enabled. Skip compacting in incremental GCs + // if we are currently animating, unless the user is inactive or we're + // responding to memory pressure. + + if (!isShrinkingGC() || !isCompactingGCEnabled()) { + return false; + } + + if (initialReason == JS::GCReason::USER_INACTIVE || + initialReason == JS::GCReason::MEM_PRESSURE) { + return true; + } + + return !isIncremental || + !IsCurrentlyAnimating(rt->lastAnimationTime, TimeStamp::Now()); +} + +bool GCRuntime::isCompactingGCEnabled() const { + return compactingEnabled && + rt->mainContextFromOwnThread()->compactingDisabledCount == 0; +} + +JS_PUBLIC_API void JS::SetCreateGCSliceBudgetCallback( + JSContext* cx, JS::CreateSliceBudgetCallback cb) { + cx->runtime()->gc.createBudgetCallback = cb; +} + +void TimeBudget::setDeadlineFromNow() { deadline = TimeStamp::Now() + budget; } + +SliceBudget::SliceBudget(TimeBudget time, InterruptRequestFlag* interrupt) + : counter(StepsPerExpensiveCheck), + interruptRequested(interrupt), + budget(TimeBudget(time)) { + budget.as().setDeadlineFromNow(); +} + +SliceBudget::SliceBudget(WorkBudget work) + : counter(work.budget), interruptRequested(nullptr), budget(work) {} + +int SliceBudget::describe(char* buffer, size_t maxlen) const { + if (isUnlimited()) { + return snprintf(buffer, maxlen, "unlimited"); + } + + if (isWorkBudget()) { + return snprintf(buffer, maxlen, "work(%" PRId64 ")", workBudget()); + } + + const char* interruptStr = ""; + if (interruptRequested) { + interruptStr = interrupted ? "INTERRUPTED " : "interruptible "; + } + const char* extra = ""; + if (idle) { + extra = extended ? " (started idle but extended)" : " (idle)"; + } + return snprintf(buffer, maxlen, "%s%" PRId64 "ms%s", interruptStr, + timeBudget(), extra); +} + +bool SliceBudget::checkOverBudget() { + MOZ_ASSERT(counter <= 0); + MOZ_ASSERT(!isUnlimited()); + + if (isWorkBudget()) { + return true; + } + + if (interruptRequested && *interruptRequested) { + interrupted = true; + } + + if (interrupted) { + return true; + } + + if (TimeStamp::Now() >= budget.as().deadline) { + return true; + } + + counter = StepsPerExpensiveCheck; + return false; +} + +void GCRuntime::requestMajorGC(JS::GCReason reason) { + MOZ_ASSERT_IF(reason != JS::GCReason::BG_TASK_FINISHED, + !CurrentThreadIsPerformingGC()); + + if (majorGCRequested()) { + return; + } + + majorGCTriggerReason = reason; + rt->mainContextFromAnyThread()->requestInterrupt(InterruptReason::MajorGC); +} + +bool GCRuntime::triggerGC(JS::GCReason reason) { + /* + * Don't trigger GCs if this is being called off the main thread from + * onTooMuchMalloc(). + */ + if (!CurrentThreadCanAccessRuntime(rt)) { + return false; + } + + /* GC is already running. */ + if (JS::RuntimeHeapIsCollecting()) { + return false; + } + + JS::PrepareForFullGC(rt->mainContextFromOwnThread()); + requestMajorGC(reason); + return true; +} + +void GCRuntime::maybeTriggerGCAfterAlloc(Zone* zone) { + MOZ_ASSERT(CurrentThreadCanAccessRuntime(rt)); + MOZ_ASSERT(!JS::RuntimeHeapIsCollecting()); + + TriggerResult trigger = + checkHeapThreshold(zone, zone->gcHeapSize, zone->gcHeapThreshold); + + if (trigger.shouldTrigger) { + // Start or continue an in progress incremental GC. We do this to try to + // avoid performing non-incremental GCs on zones which allocate a lot of + // data, even when incremental slices can't be triggered via scheduling in + // the event loop. + triggerZoneGC(zone, JS::GCReason::ALLOC_TRIGGER, trigger.usedBytes, + trigger.thresholdBytes); + } +} + +void js::gc::MaybeMallocTriggerZoneGC(JSRuntime* rt, ZoneAllocator* zoneAlloc, + const HeapSize& heap, + const HeapThreshold& threshold, + JS::GCReason reason) { + rt->gc.maybeTriggerGCAfterMalloc(Zone::from(zoneAlloc), heap, threshold, + reason); +} + +void GCRuntime::maybeTriggerGCAfterMalloc(Zone* zone) { + if (maybeTriggerGCAfterMalloc(zone, zone->mallocHeapSize, + zone->mallocHeapThreshold, + JS::GCReason::TOO_MUCH_MALLOC)) { + return; + } + + maybeTriggerGCAfterMalloc(zone, zone->jitHeapSize, zone->jitHeapThreshold, + JS::GCReason::TOO_MUCH_JIT_CODE); +} + +bool GCRuntime::maybeTriggerGCAfterMalloc(Zone* zone, const HeapSize& heap, + const HeapThreshold& threshold, + JS::GCReason reason) { + // Ignore malloc during sweeping, for example when we resize hash tables. + if (heapState() != JS::HeapState::Idle) { + return false; + } + + MOZ_ASSERT(CurrentThreadCanAccessRuntime(rt)); + + TriggerResult trigger = checkHeapThreshold(zone, heap, threshold); + if (!trigger.shouldTrigger) { + return false; + } + + // Trigger a zone GC. budgetIncrementalGC() will work out whether to do an + // incremental or non-incremental collection. + triggerZoneGC(zone, reason, trigger.usedBytes, trigger.thresholdBytes); + return true; +} + +TriggerResult GCRuntime::checkHeapThreshold( + Zone* zone, const HeapSize& heapSize, const HeapThreshold& heapThreshold) { + MOZ_ASSERT_IF(heapThreshold.hasSliceThreshold(), zone->wasGCStarted()); + + size_t usedBytes = heapSize.bytes(); + size_t thresholdBytes = heapThreshold.hasSliceThreshold() + ? heapThreshold.sliceBytes() + : heapThreshold.startBytes(); + + // The incremental limit will be checked if we trigger a GC slice. + MOZ_ASSERT(thresholdBytes <= heapThreshold.incrementalLimitBytes()); + + return TriggerResult{usedBytes >= thresholdBytes, usedBytes, thresholdBytes}; +} + +bool GCRuntime::triggerZoneGC(Zone* zone, JS::GCReason reason, size_t used, + size_t threshold) { + MOZ_ASSERT(CurrentThreadCanAccessRuntime(rt)); + + /* GC is already running. */ + if (JS::RuntimeHeapIsBusy()) { + return false; + } + +#ifdef JS_GC_ZEAL + if (hasZealMode(ZealMode::Alloc)) { + MOZ_RELEASE_ASSERT(triggerGC(reason)); + return true; + } +#endif + + if (zone->isAtomsZone()) { + stats().recordTrigger(used, threshold); + MOZ_RELEASE_ASSERT(triggerGC(reason)); + return true; + } + + stats().recordTrigger(used, threshold); + zone->scheduleGC(); + requestMajorGC(reason); + return true; +} + +void GCRuntime::maybeGC() { + MOZ_ASSERT(CurrentThreadCanAccessRuntime(rt)); + +#ifdef JS_GC_ZEAL + if (hasZealMode(ZealMode::Alloc) || hasZealMode(ZealMode::RootsChange)) { + JS::PrepareForFullGC(rt->mainContextFromOwnThread()); + gc(JS::GCOptions::Normal, JS::GCReason::DEBUG_GC); + return; + } +#endif + + (void)gcIfRequestedImpl(/* eagerOk = */ true); +} + +JS::GCReason GCRuntime::wantMajorGC(bool eagerOk) { + MOZ_ASSERT(CurrentThreadCanAccessRuntime(rt)); + + if (majorGCRequested()) { + return majorGCTriggerReason; + } + + if (isIncrementalGCInProgress() || !eagerOk) { + return JS::GCReason::NO_REASON; + } + + JS::GCReason reason = JS::GCReason::NO_REASON; + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + if (checkEagerAllocTrigger(zone->gcHeapSize, zone->gcHeapThreshold) || + checkEagerAllocTrigger(zone->mallocHeapSize, + zone->mallocHeapThreshold)) { + zone->scheduleGC(); + reason = JS::GCReason::EAGER_ALLOC_TRIGGER; + } + } + + return reason; +} + +bool GCRuntime::checkEagerAllocTrigger(const HeapSize& size, + const HeapThreshold& threshold) { + size_t thresholdBytes = + threshold.eagerAllocTrigger(schedulingState.inHighFrequencyGCMode()); + size_t usedBytes = size.bytes(); + if (usedBytes <= 1024 * 1024 || usedBytes < thresholdBytes) { + return false; + } + + stats().recordTrigger(usedBytes, thresholdBytes); + return true; +} + +bool GCRuntime::shouldDecommit() const { + // If we're doing a shrinking GC we always decommit to release as much memory + // as possible. + if (cleanUpEverything) { + return true; + } + + // If we are allocating heavily enough to trigger "high frequency" GC then + // skip decommit so that we do not compete with the mutator. + return !schedulingState.inHighFrequencyGCMode(); +} + +void GCRuntime::startDecommit() { + gcstats::AutoPhase ap(stats(), gcstats::PhaseKind::DECOMMIT); + +#ifdef DEBUG + MOZ_ASSERT(CurrentThreadCanAccessRuntime(rt)); + MOZ_ASSERT(decommitTask.isIdle()); + + { + AutoLockGC lock(this); + MOZ_ASSERT(fullChunks(lock).verify()); + MOZ_ASSERT(availableChunks(lock).verify()); + MOZ_ASSERT(emptyChunks(lock).verify()); + + // Verify that all entries in the empty chunks pool are unused. + for (ChunkPool::Iter chunk(emptyChunks(lock)); !chunk.done(); + chunk.next()) { + MOZ_ASSERT(chunk->unused()); + } + } +#endif + + if (!shouldDecommit()) { + return; + } + + { + AutoLockGC lock(this); + if (availableChunks(lock).empty() && !tooManyEmptyChunks(lock) && + emptyChunks(lock).empty()) { + return; // Nothing to do. + } + } + +#ifdef DEBUG + { + AutoLockHelperThreadState lock; + MOZ_ASSERT(!requestSliceAfterBackgroundTask); + } +#endif + + if (useBackgroundThreads) { + decommitTask.start(); + return; + } + + decommitTask.runFromMainThread(); +} + +BackgroundDecommitTask::BackgroundDecommitTask(GCRuntime* gc) + : GCParallelTask(gc, gcstats::PhaseKind::DECOMMIT) {} + +void js::gc::BackgroundDecommitTask::run(AutoLockHelperThreadState& lock) { + { + AutoUnlockHelperThreadState unlock(lock); + + ChunkPool emptyChunksToFree; + { + AutoLockGC gcLock(gc); + emptyChunksToFree = gc->expireEmptyChunkPool(gcLock); + } + + FreeChunkPool(emptyChunksToFree); + + { + AutoLockGC gcLock(gc); + + // To help minimize the total number of chunks needed over time, sort the + // available chunks list so that we allocate into more-used chunks first. + gc->availableChunks(gcLock).sort(); + + if (DecommitEnabled()) { + gc->decommitEmptyChunks(cancel_, gcLock); + gc->decommitFreeArenas(cancel_, gcLock); + } + } + } + + gc->maybeRequestGCAfterBackgroundTask(lock); +} + +static inline bool CanDecommitWholeChunk(TenuredChunk* chunk) { + return chunk->unused() && chunk->info.numArenasFreeCommitted != 0; +} + +// Called from a background thread to decommit free arenas. Releases the GC +// lock. +void GCRuntime::decommitEmptyChunks(const bool& cancel, AutoLockGC& lock) { + Vector chunksToDecommit; + for (ChunkPool::Iter chunk(emptyChunks(lock)); !chunk.done(); chunk.next()) { + if (CanDecommitWholeChunk(chunk) && !chunksToDecommit.append(chunk)) { + onOutOfMallocMemory(lock); + return; + } + } + + for (TenuredChunk* chunk : chunksToDecommit) { + if (cancel) { + break; + } + + // Check whether something used the chunk while lock was released. + if (!CanDecommitWholeChunk(chunk)) { + continue; + } + + // Temporarily remove the chunk while decommitting its memory so that the + // mutator doesn't start allocating from it when we drop the lock. + emptyChunks(lock).remove(chunk); + + { + AutoUnlockGC unlock(lock); + chunk->decommitAllArenas(); + MOZ_ASSERT(chunk->info.numArenasFreeCommitted == 0); + } + + emptyChunks(lock).push(chunk); + } +} + +// Called from a background thread to decommit free arenas. Releases the GC +// lock. +void GCRuntime::decommitFreeArenas(const bool& cancel, AutoLockGC& lock) { + MOZ_ASSERT(DecommitEnabled()); + + // Since we release the GC lock while doing the decommit syscall below, + // it is dangerous to iterate the available list directly, as the active + // thread could modify it concurrently. Instead, we build and pass an + // explicit Vector containing the Chunks we want to visit. + Vector chunksToDecommit; + for (ChunkPool::Iter chunk(availableChunks(lock)); !chunk.done(); + chunk.next()) { + if (chunk->info.numArenasFreeCommitted != 0 && + !chunksToDecommit.append(chunk)) { + onOutOfMallocMemory(lock); + return; + } + } + + for (TenuredChunk* chunk : chunksToDecommit) { + chunk->decommitFreeArenas(this, cancel, lock); + } +} + +// Do all possible decommit immediately from the current thread without +// releasing the GC lock or allocating any memory. +void GCRuntime::decommitFreeArenasWithoutUnlocking(const AutoLockGC& lock) { + MOZ_ASSERT(DecommitEnabled()); + for (ChunkPool::Iter chunk(availableChunks(lock)); !chunk.done(); + chunk.next()) { + chunk->decommitFreeArenasWithoutUnlocking(lock); + } + MOZ_ASSERT(availableChunks(lock).verify()); +} + +void GCRuntime::maybeRequestGCAfterBackgroundTask( + const AutoLockHelperThreadState& lock) { + if (requestSliceAfterBackgroundTask) { + // Trigger a slice so the main thread can continue the collection + // immediately. + requestSliceAfterBackgroundTask = false; + requestMajorGC(JS::GCReason::BG_TASK_FINISHED); + } +} + +void GCRuntime::cancelRequestedGCAfterBackgroundTask() { + MOZ_ASSERT(CurrentThreadCanAccessRuntime(rt)); + +#ifdef DEBUG + { + AutoLockHelperThreadState lock; + MOZ_ASSERT(!requestSliceAfterBackgroundTask); + } +#endif + + majorGCTriggerReason.compareExchange(JS::GCReason::BG_TASK_FINISHED, + JS::GCReason::NO_REASON); +} + +bool GCRuntime::isWaitingOnBackgroundTask() const { + AutoLockHelperThreadState lock; + return requestSliceAfterBackgroundTask; +} + +void GCRuntime::queueUnusedLifoBlocksForFree(LifoAlloc* lifo) { + MOZ_ASSERT(JS::RuntimeHeapIsBusy()); + AutoLockHelperThreadState lock; + lifoBlocksToFree.ref().transferUnusedFrom(lifo); +} + +void GCRuntime::queueAllLifoBlocksForFreeAfterMinorGC(LifoAlloc* lifo) { + lifoBlocksToFreeAfterMinorGC.ref().transferFrom(lifo); +} + +void GCRuntime::queueBuffersForFreeAfterMinorGC(Nursery::BufferSet& buffers) { + AutoLockHelperThreadState lock; + + if (!buffersToFreeAfterMinorGC.ref().empty()) { + // In the rare case that this hasn't processed the buffers from a previous + // minor GC we have to wait here. + MOZ_ASSERT(!freeTask.isIdle(lock)); + freeTask.joinWithLockHeld(lock); + } + + MOZ_ASSERT(buffersToFreeAfterMinorGC.ref().empty()); + std::swap(buffersToFreeAfterMinorGC.ref(), buffers); +} + +void Realm::destroy(JS::GCContext* gcx) { + JSRuntime* rt = gcx->runtime(); + if (auto callback = rt->destroyRealmCallback) { + callback(gcx, this); + } + if (principals()) { + JS_DropPrincipals(rt->mainContextFromOwnThread(), principals()); + } + // Bug 1560019: Malloc memory associated with a zone but not with a specific + // GC thing is not currently tracked. + gcx->deleteUntracked(this); +} + +void Compartment::destroy(JS::GCContext* gcx) { + JSRuntime* rt = gcx->runtime(); + if (auto callback = rt->destroyCompartmentCallback) { + callback(gcx, this); + } + // Bug 1560019: Malloc memory associated with a zone but not with a specific + // GC thing is not currently tracked. + gcx->deleteUntracked(this); + rt->gc.stats().sweptCompartment(); +} + +void Zone::destroy(JS::GCContext* gcx) { + MOZ_ASSERT(compartments().empty()); + JSRuntime* rt = gcx->runtime(); + if (auto callback = rt->destroyZoneCallback) { + callback(gcx, this); + } + // Bug 1560019: Malloc memory associated with a zone but not with a specific + // GC thing is not currently tracked. + gcx->deleteUntracked(this); + gcx->runtime()->gc.stats().sweptZone(); +} + +/* + * It's simpler if we preserve the invariant that every zone (except atoms + * zones) has at least one compartment, and every compartment has at least one + * realm. If we know we're deleting the entire zone, then sweepCompartments is + * allowed to delete all compartments. In this case, |keepAtleastOne| is false. + * If any cells remain alive in the zone, set |keepAtleastOne| true to prohibit + * sweepCompartments from deleting every compartment. Instead, it preserves an + * arbitrary compartment in the zone. + */ +void Zone::sweepCompartments(JS::GCContext* gcx, bool keepAtleastOne, + bool destroyingRuntime) { + MOZ_ASSERT_IF(!isAtomsZone(), !compartments().empty()); + MOZ_ASSERT_IF(destroyingRuntime, !keepAtleastOne); + + Compartment** read = compartments().begin(); + Compartment** end = compartments().end(); + Compartment** write = read; + while (read < end) { + Compartment* comp = *read++; + + /* + * Don't delete the last compartment and realm if keepAtleastOne is + * still true, meaning all the other compartments were deleted. + */ + bool keepAtleastOneRealm = read == end && keepAtleastOne; + comp->sweepRealms(gcx, keepAtleastOneRealm, destroyingRuntime); + + if (!comp->realms().empty()) { + *write++ = comp; + keepAtleastOne = false; + } else { + comp->destroy(gcx); + } + } + compartments().shrinkTo(write - compartments().begin()); + MOZ_ASSERT_IF(keepAtleastOne, !compartments().empty()); + MOZ_ASSERT_IF(destroyingRuntime, compartments().empty()); +} + +void Compartment::sweepRealms(JS::GCContext* gcx, bool keepAtleastOne, + bool destroyingRuntime) { + MOZ_ASSERT(!realms().empty()); + MOZ_ASSERT_IF(destroyingRuntime, !keepAtleastOne); + + Realm** read = realms().begin(); + Realm** end = realms().end(); + Realm** write = read; + while (read < end) { + Realm* realm = *read++; + + /* + * Don't delete the last realm if keepAtleastOne is still true, meaning + * all the other realms were deleted. + */ + bool dontDelete = read == end && keepAtleastOne; + if ((realm->marked() || dontDelete) && !destroyingRuntime) { + *write++ = realm; + keepAtleastOne = false; + } else { + realm->destroy(gcx); + } + } + realms().shrinkTo(write - realms().begin()); + MOZ_ASSERT_IF(keepAtleastOne, !realms().empty()); + MOZ_ASSERT_IF(destroyingRuntime, realms().empty()); +} + +void GCRuntime::sweepZones(JS::GCContext* gcx, bool destroyingRuntime) { + MOZ_ASSERT_IF(destroyingRuntime, numActiveZoneIters == 0); + MOZ_ASSERT(foregroundFinalizedArenas.ref().isNothing()); + + if (numActiveZoneIters) { + return; + } + + assertBackgroundSweepingFinished(); + + // Sweep zones following the atoms zone. + MOZ_ASSERT(zones()[0]->isAtomsZone()); + Zone** read = zones().begin() + 1; + Zone** end = zones().end(); + Zone** write = read; + + while (read < end) { + Zone* zone = *read++; + + if (zone->wasGCStarted()) { + MOZ_ASSERT(!zone->isQueuedForBackgroundSweep()); + AutoSetThreadIsSweeping threadIsSweeping(zone); + const bool zoneIsDead = + zone->arenas.arenaListsAreEmpty() && !zone->hasMarkedRealms(); + MOZ_ASSERT_IF(destroyingRuntime, zoneIsDead); + if (zoneIsDead) { + zone->arenas.checkEmptyFreeLists(); + zone->sweepCompartments(gcx, false, destroyingRuntime); + MOZ_ASSERT(zone->compartments().empty()); + zone->destroy(gcx); + continue; + } + zone->sweepCompartments(gcx, true, destroyingRuntime); + } + *write++ = zone; + } + zones().shrinkTo(write - zones().begin()); +} + +void ArenaLists::checkEmptyArenaList(AllocKind kind) { + MOZ_ASSERT(arenaList(kind).isEmpty()); +} + +void GCRuntime::purgeRuntimeForMinorGC() { + for (ZonesIter zone(this, SkipAtoms); !zone.done(); zone.next()) { + zone->externalStringCache().purge(); + zone->functionToStringCache().purge(); + } +} + +void GCRuntime::purgeRuntime() { + gcstats::AutoPhase ap(stats(), gcstats::PhaseKind::PURGE); + + for (GCRealmsIter realm(rt); !realm.done(); realm.next()) { + realm->purge(); + } + + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + zone->purgeAtomCache(); + zone->externalStringCache().purge(); + zone->functionToStringCache().purge(); + zone->boundPrefixCache().clearAndCompact(); + zone->shapeZone().purgeShapeCaches(rt->gcContext()); + } + + JSContext* cx = rt->mainContextFromOwnThread(); + queueUnusedLifoBlocksForFree(&cx->tempLifoAlloc()); + cx->interpreterStack().purge(rt); + cx->frontendCollectionPool().purge(); + + rt->caches().purge(); + + if (rt->isMainRuntime()) { + SharedImmutableStringsCache::getSingleton().purge(); + } + + MOZ_ASSERT(marker().unmarkGrayStack.empty()); + marker().unmarkGrayStack.clearAndFree(); +} + +bool GCRuntime::shouldPreserveJITCode(Realm* realm, + const TimeStamp& currentTime, + JS::GCReason reason, + bool canAllocateMoreCode, + bool isActiveCompartment) { + if (cleanUpEverything) { + return false; + } + if (!canAllocateMoreCode) { + return false; + } + + if (isActiveCompartment) { + return true; + } + if (alwaysPreserveCode) { + return true; + } + if (realm->preserveJitCode()) { + return true; + } + if (IsCurrentlyAnimating(realm->lastAnimationTime, currentTime) && + DiscardedCodeRecently(realm->zone(), currentTime)) { + return true; + } + if (reason == JS::GCReason::DEBUG_GC) { + return true; + } + + return false; +} + +#ifdef DEBUG +class CompartmentCheckTracer final : public JS::CallbackTracer { + void onChild(JS::GCCellPtr thing, const char* name) override; + bool edgeIsInCrossCompartmentMap(JS::GCCellPtr dst); + + public: + explicit CompartmentCheckTracer(JSRuntime* rt) + : JS::CallbackTracer(rt, JS::TracerKind::CompartmentCheck, + JS::WeakEdgeTraceAction::Skip) {} + + Cell* src = nullptr; + JS::TraceKind srcKind = JS::TraceKind::Null; + Zone* zone = nullptr; + Compartment* compartment = nullptr; +}; + +static bool InCrossCompartmentMap(JSRuntime* rt, JSObject* src, + JS::GCCellPtr dst) { + // Cross compartment edges are either in the cross compartment map or in a + // debugger weakmap. + + Compartment* srccomp = src->compartment(); + + if (dst.is()) { + if (ObjectWrapperMap::Ptr p = srccomp->lookupWrapper(&dst.as())) { + if (*p->value().unsafeGet() == src) { + return true; + } + } + } + + if (DebugAPI::edgeIsInDebuggerWeakmap(rt, src, dst)) { + return true; + } + + return false; +} + +void CompartmentCheckTracer::onChild(JS::GCCellPtr thing, const char* name) { + Compartment* comp = + MapGCThingTyped(thing, [](auto t) { return t->maybeCompartment(); }); + if (comp && compartment) { + MOZ_ASSERT(comp == compartment || edgeIsInCrossCompartmentMap(thing)); + } else { + TenuredCell* tenured = &thing.asCell()->asTenured(); + Zone* thingZone = tenured->zoneFromAnyThread(); + MOZ_ASSERT(thingZone == zone || thingZone->isAtomsZone()); + } +} + +bool CompartmentCheckTracer::edgeIsInCrossCompartmentMap(JS::GCCellPtr dst) { + return srcKind == JS::TraceKind::Object && + InCrossCompartmentMap(runtime(), static_cast(src), dst); +} + +void GCRuntime::checkForCompartmentMismatches() { + JSContext* cx = rt->mainContextFromOwnThread(); + if (cx->disableStrictProxyCheckingCount) { + return; + } + + CompartmentCheckTracer trc(rt); + AutoAssertEmptyNursery empty(cx); + for (ZonesIter zone(this, SkipAtoms); !zone.done(); zone.next()) { + trc.zone = zone; + for (auto thingKind : AllAllocKinds()) { + for (auto i = zone->cellIterUnsafe(thingKind, empty); + !i.done(); i.next()) { + trc.src = i.getCell(); + trc.srcKind = MapAllocToTraceKind(thingKind); + trc.compartment = MapGCThingTyped( + trc.src, trc.srcKind, [](auto t) { return t->maybeCompartment(); }); + JS::TraceChildren(&trc, JS::GCCellPtr(trc.src, trc.srcKind)); + } + } + } +} +#endif + +static bool ShouldCleanUpEverything(JS::GCOptions options) { + // During shutdown, we must clean everything up, for the sake of leak + // detection. When a runtime has no contexts, or we're doing a GC before a + // shutdown CC, those are strong indications that we're shutting down. + return options == JS::GCOptions::Shutdown || options == JS::GCOptions::Shrink; +} + +static bool ShouldUseBackgroundThreads(bool isIncremental, + JS::GCReason reason) { + bool shouldUse = isIncremental && CanUseExtraThreads(); + MOZ_ASSERT_IF(reason == JS::GCReason::DESTROY_RUNTIME, !shouldUse); + return shouldUse; +} + +void GCRuntime::startCollection(JS::GCReason reason) { + checkGCStateNotInUse(); + MOZ_ASSERT_IF( + isShuttingDown(), + isShutdownGC() || + reason == JS::GCReason::XPCONNECT_SHUTDOWN /* Bug 1650075 */); + + initialReason = reason; + cleanUpEverything = ShouldCleanUpEverything(gcOptions()); + isCompacting = shouldCompact(); + rootsRemoved = false; + sweepGroupIndex = 0; + lastGCStartTime_ = TimeStamp::Now(); + +#ifdef DEBUG + if (isShutdownGC()) { + hadShutdownGC = true; + } + + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + zone->gcSweepGroupIndex = 0; + } +#endif +} + +static void RelazifyFunctions(Zone* zone, AllocKind kind) { + MOZ_ASSERT(kind == AllocKind::FUNCTION || + kind == AllocKind::FUNCTION_EXTENDED); + + JSRuntime* rt = zone->runtimeFromMainThread(); + AutoAssertEmptyNursery empty(rt->mainContextFromOwnThread()); + + for (auto i = zone->cellIterUnsafe(kind, empty); !i.done(); + i.next()) { + JSFunction* fun = &i->as(); + // When iterating over the GC-heap, we may encounter function objects that + // are incomplete (missing a BaseScript when we expect one). We must check + // for this case before we can call JSFunction::hasBytecode(). + if (fun->isIncomplete()) { + continue; + } + if (fun->hasBytecode()) { + fun->maybeRelazify(rt); + } + } +} + +static bool ShouldCollectZone(Zone* zone, JS::GCReason reason) { + // If we are repeating a GC because we noticed dead compartments haven't + // been collected, then only collect zones containing those compartments. + if (reason == JS::GCReason::COMPARTMENT_REVIVED) { + for (CompartmentsInZoneIter comp(zone); !comp.done(); comp.next()) { + if (comp->gcState.scheduledForDestruction) { + return true; + } + } + + return false; + } + + // Otherwise we only collect scheduled zones. + return zone->isGCScheduled(); +} + +bool GCRuntime::prepareZonesForCollection(JS::GCReason reason, + bool* isFullOut) { +#ifdef DEBUG + /* Assert that zone state is as we expect */ + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + MOZ_ASSERT(!zone->isCollecting()); + MOZ_ASSERT_IF(!zone->isAtomsZone(), !zone->compartments().empty()); + for (auto i : AllAllocKinds()) { + MOZ_ASSERT(zone->arenas.collectingArenaList(i).isEmpty()); + } + } +#endif + + *isFullOut = true; + bool any = false; + + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + /* Set up which zones will be collected. */ + bool shouldCollect = ShouldCollectZone(zone, reason); + if (shouldCollect) { + any = true; + zone->changeGCState(Zone::NoGC, Zone::Prepare); + } else { + *isFullOut = false; + } + + zone->setWasCollected(shouldCollect); + } + + /* Check that at least one zone is scheduled for collection. */ + return any; +} + +void GCRuntime::discardJITCodeForGC() { + size_t nurserySiteResetCount = 0; + size_t pretenuredSiteResetCount = 0; + + js::CancelOffThreadIonCompile(rt, JS::Zone::Prepare); + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + gcstats::AutoPhase ap(stats(), gcstats::PhaseKind::MARK_DISCARD_CODE); + + // We may need to reset allocation sites and discard JIT code to recover if + // we find object lifetimes have changed. + PretenuringZone& pz = zone->pretenuring; + bool resetNurserySites = pz.shouldResetNurseryAllocSites(); + bool resetPretenuredSites = pz.shouldResetPretenuredAllocSites(); + + if (!zone->isPreservingCode()) { + Zone::DiscardOptions options; + options.discardJitScripts = true; + options.resetNurseryAllocSites = resetNurserySites; + options.resetPretenuredAllocSites = resetPretenuredSites; + zone->discardJitCode(rt->gcContext(), options); + } else if (resetNurserySites || resetPretenuredSites) { + zone->resetAllocSitesAndInvalidate(resetNurserySites, + resetPretenuredSites); + } + + if (resetNurserySites) { + nurserySiteResetCount++; + } + if (resetPretenuredSites) { + pretenuredSiteResetCount++; + } + } + + if (nursery().reportPretenuring()) { + if (nurserySiteResetCount) { + fprintf( + stderr, + "GC reset nursery alloc sites and invalidated code in %zu zones\n", + nurserySiteResetCount); + } + if (pretenuredSiteResetCount) { + fprintf( + stderr, + "GC reset pretenured alloc sites and invalidated code in %zu zones\n", + pretenuredSiteResetCount); + } + } +} + +void GCRuntime::relazifyFunctionsForShrinkingGC() { + gcstats::AutoPhase ap(stats(), gcstats::PhaseKind::RELAZIFY_FUNCTIONS); + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + RelazifyFunctions(zone, AllocKind::FUNCTION); + RelazifyFunctions(zone, AllocKind::FUNCTION_EXTENDED); + } +} + +void GCRuntime::purgePropMapTablesForShrinkingGC() { + gcstats::AutoPhase ap(stats(), gcstats::PhaseKind::PURGE_PROP_MAP_TABLES); + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + if (!canRelocateZone(zone) || zone->keepPropMapTables()) { + continue; + } + + // Note: CompactPropMaps never have a table. + for (auto map = zone->cellIterUnsafe(); !map.done(); + map.next()) { + if (map->asLinked()->hasTable()) { + map->asLinked()->purgeTable(rt->gcContext()); + } + } + for (auto map = zone->cellIterUnsafe(); !map.done(); + map.next()) { + if (map->asLinked()->hasTable()) { + map->asLinked()->purgeTable(rt->gcContext()); + } + } + } +} + +// The debugger keeps track of the URLs for the sources of each realm's scripts. +// These URLs are purged on shrinking GCs. +void GCRuntime::purgeSourceURLsForShrinkingGC() { + gcstats::AutoPhase ap(stats(), gcstats::PhaseKind::PURGE_SOURCE_URLS); + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + // URLs are not tracked for realms in the system zone. + if (!canRelocateZone(zone) || zone->isSystemZone()) { + continue; + } + for (CompartmentsInZoneIter comp(zone); !comp.done(); comp.next()) { + for (RealmsInCompartmentIter realm(comp); !realm.done(); realm.next()) { + GlobalObject* global = realm.get()->unsafeUnbarrieredMaybeGlobal(); + if (global) { + global->clearSourceURLSHolder(); + } + } + } + } +} + +void GCRuntime::unmarkWeakMaps() { + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + /* Unmark all weak maps in the zones being collected. */ + WeakMapBase::unmarkZone(zone); + } +} + +bool GCRuntime::beginPreparePhase(JS::GCReason reason, AutoGCSession& session) { + gcstats::AutoPhase ap(stats(), gcstats::PhaseKind::PREPARE); + + if (!prepareZonesForCollection(reason, &isFull.ref())) { + return false; + } + + /* + * Start a parallel task to clear all mark state for the zones we are + * collecting. This is linear in the size of the heap we are collecting and so + * can be slow. This usually happens concurrently with the mutator and GC + * proper does not start until this is complete. + */ + unmarkTask.initZones(); + if (useBackgroundThreads) { + unmarkTask.start(); + } else { + unmarkTask.runFromMainThread(); + } + + /* + * Process any queued source compressions during the start of a major + * GC. + * + * Bug 1650075: When we start passing GCOptions::Shutdown for + * GCReason::XPCONNECT_SHUTDOWN GCs we can remove the extra check. + */ + if (!isShutdownGC() && reason != JS::GCReason::XPCONNECT_SHUTDOWN) { + StartHandlingCompressionsOnGC(rt); + } + + return true; +} + +BackgroundUnmarkTask::BackgroundUnmarkTask(GCRuntime* gc) + : GCParallelTask(gc, gcstats::PhaseKind::UNMARK) {} + +void BackgroundUnmarkTask::initZones() { + MOZ_ASSERT(isIdle()); + MOZ_ASSERT(zones.empty()); + MOZ_ASSERT(!isCancelled()); + + // We can't safely iterate the zones vector from another thread so we copy the + // zones to be collected into another vector. + AutoEnterOOMUnsafeRegion oomUnsafe; + for (GCZonesIter zone(gc); !zone.done(); zone.next()) { + if (!zones.append(zone.get())) { + oomUnsafe.crash("BackgroundUnmarkTask::initZones"); + } + + zone->arenas.clearFreeLists(); + zone->arenas.moveArenasToCollectingLists(); + } +} + +void BackgroundUnmarkTask::run(AutoLockHelperThreadState& helperTheadLock) { + AutoUnlockHelperThreadState unlock(helperTheadLock); + + for (Zone* zone : zones) { + for (auto kind : AllAllocKinds()) { + ArenaList& arenas = zone->arenas.collectingArenaList(kind); + for (ArenaListIter arena(arenas.head()); !arena.done(); arena.next()) { + arena->unmarkAll(); + if (isCancelled()) { + break; + } + } + } + } + + zones.clear(); +} + +void GCRuntime::endPreparePhase(JS::GCReason reason) { + MOZ_ASSERT(unmarkTask.isIdle()); + + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + /* + * In an incremental GC, clear the area free lists to ensure that subsequent + * allocations refill them and end up marking new cells back. See + * arenaAllocatedDuringGC(). + */ + zone->arenas.clearFreeLists(); + + zone->setPreservingCode(false); + +#ifdef JS_GC_ZEAL + if (hasZealMode(ZealMode::YieldBeforeRootMarking)) { + for (auto kind : AllAllocKinds()) { + for (ArenaIterInGC arena(zone, kind); !arena.done(); arena.next()) { + arena->checkNoMarkedCells(); + } + } + } +#endif + } + + // Discard JIT code more aggressively if the process is approaching its + // executable code limit. + bool canAllocateMoreCode = jit::CanLikelyAllocateMoreExecutableMemory(); + auto currentTime = TimeStamp::Now(); + + Compartment* activeCompartment = nullptr; + jit::JitActivationIterator activation(rt->mainContextFromOwnThread()); + if (!activation.done()) { + activeCompartment = activation->compartment(); + } + + for (CompartmentsIter c(rt); !c.done(); c.next()) { + c->gcState.scheduledForDestruction = false; + c->gcState.maybeAlive = false; + c->gcState.hasEnteredRealm = false; + if (c->invisibleToDebugger()) { + c->gcState.maybeAlive = true; // Presumed to be a system compartment. + } + bool isActiveCompartment = c == activeCompartment; + for (RealmsInCompartmentIter r(c); !r.done(); r.next()) { + if (r->shouldTraceGlobal() || !r->zone()->isGCScheduled()) { + c->gcState.maybeAlive = true; + } + if (shouldPreserveJITCode(r, currentTime, reason, canAllocateMoreCode, + isActiveCompartment)) { + r->zone()->setPreservingCode(true); + } + if (r->hasBeenEnteredIgnoringJit()) { + c->gcState.hasEnteredRealm = true; + } + } + } + + /* + * Perform remaining preparation work that must take place in the first true + * GC slice. + */ + + { + gcstats::AutoPhase ap1(stats(), gcstats::PhaseKind::PREPARE); + + AutoLockHelperThreadState helperLock; + + /* Clear mark state for WeakMaps in parallel with other work. */ + AutoRunParallelTask unmarkWeakMaps(this, &GCRuntime::unmarkWeakMaps, + gcstats::PhaseKind::UNMARK_WEAKMAPS, + GCUse::Unspecified, helperLock); + + AutoUnlockHelperThreadState unlock(helperLock); + + // Discard JIT code. For incremental collections, the sweep phase may + // also discard JIT code. + discardJITCodeForGC(); + haveDiscardedJITCodeThisSlice = true; + + /* + * Relazify functions after discarding JIT code (we can't relazify + * functions with JIT code) and before the actual mark phase, so that + * the current GC can collect the JSScripts we're unlinking here. We do + * this only when we're performing a shrinking GC, as too much + * relazification can cause performance issues when we have to reparse + * the same functions over and over. + */ + if (isShrinkingGC()) { + relazifyFunctionsForShrinkingGC(); + purgePropMapTablesForShrinkingGC(); + purgeSourceURLsForShrinkingGC(); + } + + /* + * We must purge the runtime at the beginning of an incremental GC. The + * danger if we purge later is that the snapshot invariant of + * incremental GC will be broken, as follows. If some object is + * reachable only through some cache (say the dtoaCache) then it will + * not be part of the snapshot. If we purge after root marking, then + * the mutator could obtain a pointer to the object and start using + * it. This object might never be marked, so a GC hazard would exist. + */ + purgeRuntime(); + + startBackgroundFreeAfterMinorGC(); + + if (isShutdownGC()) { + /* Clear any engine roots that may hold external data live. */ + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + zone->clearRootsForShutdownGC(); + } + +#ifdef DEBUG + testMarkQueue.clear(); + queuePos = 0; +#endif + } + } + +#ifdef DEBUG + if (fullCompartmentChecks) { + checkForCompartmentMismatches(); + } +#endif +} + +AutoUpdateLiveCompartments::AutoUpdateLiveCompartments(GCRuntime* gc) : gc(gc) { + for (GCCompartmentsIter c(gc->rt); !c.done(); c.next()) { + c->gcState.hasMarkedCells = false; + } +} + +AutoUpdateLiveCompartments::~AutoUpdateLiveCompartments() { + for (GCCompartmentsIter c(gc->rt); !c.done(); c.next()) { + if (c->gcState.hasMarkedCells) { + c->gcState.maybeAlive = true; + } + } +} + +Zone::GCState Zone::initialMarkingState() const { + if (isAtomsZone()) { + // Don't delay gray marking in the atoms zone like we do in other zones. + return MarkBlackAndGray; + } + + return MarkBlackOnly; +} + +void GCRuntime::beginMarkPhase(AutoGCSession& session) { + /* + * Mark phase. + */ + gcstats::AutoPhase ap(stats(), gcstats::PhaseKind::MARK); + + // This is the slice we actually start collecting. The number can be used to + // check whether a major GC has started so we must not increment it until we + // get here. + incMajorGcNumber(); + +#ifdef DEBUG + queuePos = 0; + queueMarkColor.reset(); +#endif + + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + // Incremental marking barriers are enabled at this point. + zone->changeGCState(Zone::Prepare, zone->initialMarkingState()); + + // Merge arenas allocated during the prepare phase, then move all arenas to + // the collecting arena lists. + zone->arenas.mergeArenasFromCollectingLists(); + zone->arenas.moveArenasToCollectingLists(); + + for (RealmsInZoneIter realm(zone); !realm.done(); realm.next()) { + realm->clearAllocatedDuringGC(); + } + } + + updateSchedulingStateOnGCStart(); + stats().measureInitialHeapSize(); + + useParallelMarking = SingleThreadedMarking; + if (canMarkInParallel() && initParallelMarkers()) { + useParallelMarking = AllowParallelMarking; + } + + MOZ_ASSERT(!hasDelayedMarking()); + for (auto& marker : markers) { + marker->start(); + } + + if (rt->isBeingDestroyed()) { + checkNoRuntimeRoots(session); + } else { + AutoUpdateLiveCompartments updateLive(this); + marker().setRootMarkingMode(true); + traceRuntimeForMajorGC(marker().tracer(), session); + marker().setRootMarkingMode(false); + } +} + +void GCRuntime::findDeadCompartments() { + gcstats::AutoPhase ap1(stats(), gcstats::PhaseKind::FIND_DEAD_COMPARTMENTS); + + /* + * This code ensures that if a compartment is "dead", then it will be + * collected in this GC. A compartment is considered dead if its maybeAlive + * flag is false. The maybeAlive flag is set if: + * + * (1) the compartment has been entered (set in beginMarkPhase() above) + * (2) the compartment's zone is not being collected (set in + * endPreparePhase() above) + * (3) an object in the compartment was marked during root marking, either + * as a black root or a gray root. This is arranged by + * SetCompartmentHasMarkedCells and AutoUpdateLiveCompartments. + * (4) the compartment has incoming cross-compartment edges from another + * compartment that has maybeAlive set (set by this method). + * (5) the compartment has the invisibleToDebugger flag set, as it is + * presumed to be a system compartment (set in endPreparePhase() above) + * + * If the maybeAlive is false, then we set the scheduledForDestruction flag. + * At the end of the GC, we look for compartments where + * scheduledForDestruction is true. These are compartments that were somehow + * "revived" during the incremental GC. If any are found, we do a special, + * non-incremental GC of those compartments to try to collect them. + * + * Compartments can be revived for a variety of reasons, including: + * + * (1) A dead reflector can be revived by DOM code that still refers to the + * underlying DOM node (see bug 811587). + * (2) JS_TransplantObject iterates over all compartments, live or dead, and + * operates on their objects. This can trigger read barriers and mark + * unreachable objects. See bug 803376 for details on this problem. To + * avoid the problem, we try to avoid allocation and read barriers + * during JS_TransplantObject and the like. + * (3) Read barriers. A compartment may only have weak roots and reading one + * of these will cause the compartment to stay alive even though the GC + * thought it should die. An example of this is Gecko's unprivileged + * junk scope, which is handled by ignoring system compartments (see bug + * 1868437). + */ + + // Propagate the maybeAlive flag via cross-compartment edges. + + Vector workList; + + for (CompartmentsIter comp(rt); !comp.done(); comp.next()) { + if (comp->gcState.maybeAlive) { + if (!workList.append(comp)) { + return; + } + } + } + + while (!workList.empty()) { + Compartment* comp = workList.popCopy(); + for (Compartment::WrappedObjectCompartmentEnum e(comp); !e.empty(); + e.popFront()) { + Compartment* dest = e.front(); + if (!dest->gcState.maybeAlive) { + dest->gcState.maybeAlive = true; + if (!workList.append(dest)) { + return; + } + } + } + } + + // Set scheduledForDestruction based on maybeAlive. + + for (GCCompartmentsIter comp(rt); !comp.done(); comp.next()) { + MOZ_ASSERT(!comp->gcState.scheduledForDestruction); + if (!comp->gcState.maybeAlive) { + comp->gcState.scheduledForDestruction = true; + } + } +} + +void GCRuntime::updateSchedulingStateOnGCStart() { + heapSize.updateOnGCStart(); + + // Update memory counters for the zones we are collecting. + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + zone->updateSchedulingStateOnGCStart(); + } +} + +inline bool GCRuntime::canMarkInParallel() const { + MOZ_ASSERT(state() >= gc::State::MarkRoots); + +#if defined(DEBUG) || defined(JS_OOM_BREAKPOINT) + // OOM testing limits the engine to using a single helper thread. + if (oom::simulator.targetThread() == THREAD_TYPE_GCPARALLEL) { + return false; + } +#endif + + return markers.length() > 1 && stats().initialCollectedBytes() >= + tunables.parallelMarkingThresholdBytes(); +} + +bool GCRuntime::initParallelMarkers() { + MOZ_ASSERT(canMarkInParallel()); + + // Allocate stack for parallel markers. The first marker always has stack + // allocated. Other markers have their stack freed in + // GCRuntime::finishCollection. + for (size_t i = 1; i < markers.length(); i++) { + if (!markers[i]->initStack()) { + return false; + } + } + + return true; +} + +IncrementalProgress GCRuntime::markUntilBudgetExhausted( + SliceBudget& sliceBudget, ParallelMarking allowParallelMarking, + ShouldReportMarkTime reportTime) { + // Run a marking slice and return whether the stack is now empty. + + AutoMajorGCProfilerEntry s(this); + + if (initialState != State::Mark) { + sliceBudget.forceCheck(); + if (sliceBudget.isOverBudget()) { + return NotFinished; + } + } + + if (processTestMarkQueue() == QueueYielded) { + return NotFinished; + } + + if (allowParallelMarking) { + MOZ_ASSERT(canMarkInParallel()); + MOZ_ASSERT(parallelMarkingEnabled); + MOZ_ASSERT(reportTime); + MOZ_ASSERT(!isBackgroundMarking()); + + ParallelMarker pm(this); + if (!pm.mark(sliceBudget)) { + return NotFinished; + } + + assertNoMarkingWork(); + return Finished; + } + +#ifdef DEBUG + AutoSetThreadIsMarking threadIsMarking; +#endif // DEBUG + + return marker().markUntilBudgetExhausted(sliceBudget, reportTime) + ? Finished + : NotFinished; +} + +void GCRuntime::drainMarkStack() { + auto unlimited = SliceBudget::unlimited(); + MOZ_RELEASE_ASSERT(marker().markUntilBudgetExhausted(unlimited)); +} + +#ifdef DEBUG + +const GCVector, 0, SystemAllocPolicy>& +GCRuntime::getTestMarkQueue() const { + return testMarkQueue.get(); +} + +bool GCRuntime::appendTestMarkQueue(const JS::Value& value) { + return testMarkQueue.append(value); +} + +void GCRuntime::clearTestMarkQueue() { + testMarkQueue.clear(); + queuePos = 0; +} + +size_t GCRuntime::testMarkQueuePos() const { return queuePos; } + +#endif + +GCRuntime::MarkQueueProgress GCRuntime::processTestMarkQueue() { +#ifdef DEBUG + if (testMarkQueue.empty()) { + return QueueComplete; + } + + if (queueMarkColor == mozilla::Some(MarkColor::Gray) && + state() != State::Sweep) { + return QueueSuspended; + } + + // If the queue wants to be gray marking, but we've pushed a black object + // since set-color-gray was processed, then we can't switch to gray and must + // again wait until gray marking is possible. + // + // Remove this code if the restriction against marking gray during black is + // relaxed. + if (queueMarkColor == mozilla::Some(MarkColor::Gray) && + marker().hasBlackEntries()) { + return QueueSuspended; + } + + // If the queue wants to be marking a particular color, switch to that color. + // In any case, restore the mark color to whatever it was when we entered + // this function. + bool willRevertToGray = marker().markColor() == MarkColor::Gray; + AutoSetMarkColor autoRevertColor( + marker(), queueMarkColor.valueOr(marker().markColor())); + + // Process the mark queue by taking each object in turn, pushing it onto the + // mark stack, and processing just the top element with processMarkStackTop + // without recursing into reachable objects. + while (queuePos < testMarkQueue.length()) { + Value val = testMarkQueue[queuePos++].get(); + if (val.isObject()) { + JSObject* obj = &val.toObject(); + JS::Zone* zone = obj->zone(); + if (!zone->isGCMarking() || obj->isMarkedAtLeast(marker().markColor())) { + continue; + } + + // If we have started sweeping, obey sweep group ordering. But note that + // we will first be called during the initial sweep slice, when the sweep + // group indexes have not yet been computed. In that case, we can mark + // freely. + if (state() == State::Sweep && initialState != State::Sweep) { + if (zone->gcSweepGroupIndex < getCurrentSweepGroupIndex()) { + // Too late. This must have been added after we started collecting, + // and we've already processed its sweep group. Skip it. + continue; + } + if (zone->gcSweepGroupIndex > getCurrentSweepGroupIndex()) { + // Not ready yet. Wait until we reach the object's sweep group. + queuePos--; + return QueueSuspended; + } + } + + if (marker().markColor() == MarkColor::Gray && + zone->isGCMarkingBlackOnly()) { + // Have not yet reached the point where we can mark this object, so + // continue with the GC. + queuePos--; + return QueueSuspended; + } + + if (marker().markColor() == MarkColor::Black && willRevertToGray) { + // If we put any black objects on the stack, we wouldn't be able to + // return to gray marking. So delay the marking until we're back to + // black marking. + queuePos--; + return QueueSuspended; + } + + // Mark the object. + AutoEnterOOMUnsafeRegion oomUnsafe; + if (!marker().markOneObjectForTest(obj)) { + // If we overflowed the stack here and delayed marking, then we won't be + // testing what we think we're testing. + MOZ_ASSERT(obj->asTenured().arena()->onDelayedMarkingList()); + oomUnsafe.crash("Overflowed stack while marking test queue"); + } + } else if (val.isString()) { + JSLinearString* str = &val.toString()->asLinear(); + if (js::StringEqualsLiteral(str, "yield") && isIncrementalGc()) { + return QueueYielded; + } + + if (js::StringEqualsLiteral(str, "enter-weak-marking-mode") || + js::StringEqualsLiteral(str, "abort-weak-marking-mode")) { + if (marker().isRegularMarking()) { + // We can't enter weak marking mode at just any time, so instead + // we'll stop processing the queue and continue on with the GC. Once + // we enter weak marking mode, we can continue to the rest of the + // queue. Note that we will also suspend for aborting, and then abort + // the earliest following weak marking mode. + queuePos--; + return QueueSuspended; + } + if (js::StringEqualsLiteral(str, "abort-weak-marking-mode")) { + marker().abortLinearWeakMarking(); + } + } else if (js::StringEqualsLiteral(str, "drain")) { + auto unlimited = SliceBudget::unlimited(); + MOZ_RELEASE_ASSERT( + marker().markUntilBudgetExhausted(unlimited, DontReportMarkTime)); + } else if (js::StringEqualsLiteral(str, "set-color-gray")) { + queueMarkColor = mozilla::Some(MarkColor::Gray); + if (state() != State::Sweep || marker().hasBlackEntries()) { + // Cannot mark gray yet, so continue with the GC. + queuePos--; + return QueueSuspended; + } + marker().setMarkColor(MarkColor::Gray); + } else if (js::StringEqualsLiteral(str, "set-color-black")) { + queueMarkColor = mozilla::Some(MarkColor::Black); + marker().setMarkColor(MarkColor::Black); + } else if (js::StringEqualsLiteral(str, "unset-color")) { + queueMarkColor.reset(); + } + } + } +#endif + + return QueueComplete; +} + +static bool IsEmergencyGC(JS::GCReason reason) { + return reason == JS::GCReason::LAST_DITCH || + reason == JS::GCReason::MEM_PRESSURE; +} + +void GCRuntime::finishCollection(JS::GCReason reason) { + assertBackgroundSweepingFinished(); + + MOZ_ASSERT(!hasDelayedMarking()); + for (size_t i = 0; i < markers.length(); i++) { + const auto& marker = markers[i]; + marker->stop(); + if (i == 0) { + marker->resetStackCapacity(); + } else { + marker->freeStack(); + } + } + + maybeStopPretenuring(); + + if (IsEmergencyGC(reason)) { + waitBackgroundFreeEnd(); + } + + TimeStamp currentTime = TimeStamp::Now(); + + updateSchedulingStateAfterCollection(currentTime); + + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + zone->changeGCState(Zone::Finished, Zone::NoGC); + zone->notifyObservingDebuggers(); + } + +#ifdef JS_GC_ZEAL + clearSelectedForMarking(); +#endif + + schedulingState.updateHighFrequencyMode(lastGCEndTime_, currentTime, + tunables); + lastGCEndTime_ = currentTime; + + checkGCStateNotInUse(); +} + +void GCRuntime::checkGCStateNotInUse() { +#ifdef DEBUG + for (auto& marker : markers) { + MOZ_ASSERT(!marker->isActive()); + MOZ_ASSERT(marker->isDrained()); + } + MOZ_ASSERT(!hasDelayedMarking()); + + MOZ_ASSERT(!lastMarkSlice); + + MOZ_ASSERT(foregroundFinalizedArenas.ref().isNothing()); + + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + if (zone->wasCollected()) { + zone->arenas.checkGCStateNotInUse(); + } + MOZ_ASSERT(!zone->wasGCStarted()); + MOZ_ASSERT(!zone->needsIncrementalBarrier()); + MOZ_ASSERT(!zone->isOnList()); + } + + MOZ_ASSERT(zonesToMaybeCompact.ref().isEmpty()); + MOZ_ASSERT(cellsToAssertNotGray.ref().empty()); + + AutoLockHelperThreadState lock; + MOZ_ASSERT(!requestSliceAfterBackgroundTask); + MOZ_ASSERT(unmarkTask.isIdle(lock)); + MOZ_ASSERT(markTask.isIdle(lock)); + MOZ_ASSERT(sweepTask.isIdle(lock)); + MOZ_ASSERT(decommitTask.isIdle(lock)); +#endif +} + +void GCRuntime::maybeStopPretenuring() { + nursery().maybeStopPretenuring(this); + + size_t zonesWhereStringsEnabled = 0; + size_t zonesWhereBigIntsEnabled = 0; + + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + if (zone->nurseryStringsDisabled || zone->nurseryBigIntsDisabled) { + // We may need to reset allocation sites and discard JIT code to recover + // if we find object lifetimes have changed. + if (zone->pretenuring.shouldResetPretenuredAllocSites()) { + zone->unknownAllocSite(JS::TraceKind::String)->maybeResetState(); + zone->unknownAllocSite(JS::TraceKind::BigInt)->maybeResetState(); + if (zone->nurseryStringsDisabled) { + zone->nurseryStringsDisabled = false; + zonesWhereStringsEnabled++; + } + if (zone->nurseryBigIntsDisabled) { + zone->nurseryBigIntsDisabled = false; + zonesWhereBigIntsEnabled++; + } + nursery().updateAllocFlagsForZone(zone); + } + } + } + + if (nursery().reportPretenuring()) { + if (zonesWhereStringsEnabled) { + fprintf(stderr, "GC re-enabled nursery string allocation in %zu zones\n", + zonesWhereStringsEnabled); + } + if (zonesWhereBigIntsEnabled) { + fprintf(stderr, "GC re-enabled nursery big int allocation in %zu zones\n", + zonesWhereBigIntsEnabled); + } + } +} + +void GCRuntime::updateSchedulingStateAfterCollection(TimeStamp currentTime) { + TimeDuration totalGCTime = stats().totalGCTime(); + size_t totalInitialBytes = stats().initialCollectedBytes(); + + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + if (tunables.balancedHeapLimitsEnabled() && totalInitialBytes != 0) { + zone->updateCollectionRate(totalGCTime, totalInitialBytes); + } + zone->clearGCSliceThresholds(); + zone->updateGCStartThresholds(*this); + } +} + +void GCRuntime::updateAllGCStartThresholds() { + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + zone->updateGCStartThresholds(*this); + } +} + +void GCRuntime::updateAllocationRates() { + // Calculate mutator time since the last update. This ignores the fact that + // the zone could have been created since the last update. + + TimeStamp currentTime = TimeStamp::Now(); + TimeDuration totalTime = currentTime - lastAllocRateUpdateTime; + if (collectorTimeSinceAllocRateUpdate >= totalTime) { + // It shouldn't happen but occasionally we see collector time being larger + // than total time. Skip the update in that case. + return; + } + + TimeDuration mutatorTime = totalTime - collectorTimeSinceAllocRateUpdate; + + for (AllZonesIter zone(this); !zone.done(); zone.next()) { + zone->updateAllocationRate(mutatorTime); + zone->updateGCStartThresholds(*this); + } + + lastAllocRateUpdateTime = currentTime; + collectorTimeSinceAllocRateUpdate = TimeDuration::Zero(); +} + +static const char* GCHeapStateToLabel(JS::HeapState heapState) { + switch (heapState) { + case JS::HeapState::MinorCollecting: + return "Minor GC"; + case JS::HeapState::MajorCollecting: + return "Major GC"; + default: + MOZ_CRASH("Unexpected heap state when pushing GC profiling stack frame"); + } + MOZ_ASSERT_UNREACHABLE("Should have exhausted every JS::HeapState variant!"); + return nullptr; +} + +static JS::ProfilingCategoryPair GCHeapStateToProfilingCategory( + JS::HeapState heapState) { + return heapState == JS::HeapState::MinorCollecting + ? JS::ProfilingCategoryPair::GCCC_MinorGC + : JS::ProfilingCategoryPair::GCCC_MajorGC; +} + +/* Start a new heap session. */ +AutoHeapSession::AutoHeapSession(GCRuntime* gc, JS::HeapState heapState) + : gc(gc), prevState(gc->heapState_) { + MOZ_ASSERT(CurrentThreadCanAccessRuntime(gc->rt)); + MOZ_ASSERT(prevState == JS::HeapState::Idle || + (prevState == JS::HeapState::MajorCollecting && + heapState == JS::HeapState::MinorCollecting)); + MOZ_ASSERT(heapState != JS::HeapState::Idle); + + gc->heapState_ = heapState; + + if (heapState == JS::HeapState::MinorCollecting || + heapState == JS::HeapState::MajorCollecting) { + profilingStackFrame.emplace( + gc->rt->mainContextFromOwnThread(), GCHeapStateToLabel(heapState), + GCHeapStateToProfilingCategory(heapState), + uint32_t(ProfilingStackFrame::Flags::RELEVANT_FOR_JS)); + } +} + +AutoHeapSession::~AutoHeapSession() { + MOZ_ASSERT(JS::RuntimeHeapIsBusy()); + gc->heapState_ = prevState; +} + +static const char* MajorGCStateToLabel(State state) { + switch (state) { + case State::Mark: + return "js::GCRuntime::markUntilBudgetExhausted"; + case State::Sweep: + return "js::GCRuntime::performSweepActions"; + case State::Compact: + return "js::GCRuntime::compactPhase"; + default: + MOZ_CRASH("Unexpected heap state when pushing GC profiling stack frame"); + } + + MOZ_ASSERT_UNREACHABLE("Should have exhausted every State variant!"); + return nullptr; +} + +static JS::ProfilingCategoryPair MajorGCStateToProfilingCategory(State state) { + switch (state) { + case State::Mark: + return JS::ProfilingCategoryPair::GCCC_MajorGC_Mark; + case State::Sweep: + return JS::ProfilingCategoryPair::GCCC_MajorGC_Sweep; + case State::Compact: + return JS::ProfilingCategoryPair::GCCC_MajorGC_Compact; + default: + MOZ_CRASH("Unexpected heap state when pushing GC profiling stack frame"); + } +} + +AutoMajorGCProfilerEntry::AutoMajorGCProfilerEntry(GCRuntime* gc) + : AutoGeckoProfilerEntry(gc->rt->mainContextFromAnyThread(), + MajorGCStateToLabel(gc->state()), + MajorGCStateToProfilingCategory(gc->state())) { + MOZ_ASSERT(gc->heapState() == JS::HeapState::MajorCollecting); +} + +GCRuntime::IncrementalResult GCRuntime::resetIncrementalGC( + GCAbortReason reason) { + MOZ_ASSERT(reason != GCAbortReason::None); + + // Drop as much work as possible from an ongoing incremental GC so + // we can start a new GC after it has finished. + if (incrementalState == State::NotActive) { + return IncrementalResult::Ok; + } + + AutoGCSession session(this, JS::HeapState::MajorCollecting); + + switch (incrementalState) { + case State::NotActive: + case State::MarkRoots: + case State::Finish: + MOZ_CRASH("Unexpected GC state in resetIncrementalGC"); + break; + + case State::Prepare: + unmarkTask.cancelAndWait(); + + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + zone->changeGCState(Zone::Prepare, Zone::NoGC); + zone->clearGCSliceThresholds(); + zone->arenas.clearFreeLists(); + zone->arenas.mergeArenasFromCollectingLists(); + } + + incrementalState = State::NotActive; + checkGCStateNotInUse(); + break; + + case State::Mark: { + // Cancel any ongoing marking. + for (auto& marker : markers) { + marker->reset(); + } + resetDelayedMarking(); + + for (GCCompartmentsIter c(rt); !c.done(); c.next()) { + resetGrayList(c); + } + + for (GCZonesIter zone(this); !zone.done(); zone.next()) { + zone->changeGCState(zone->initialMarkingState(), Zone::NoGC); + zone->clearGCSliceThresholds(); + zone->arenas.unmarkPreMarkedFreeCells(); + zone->arenas.mergeArenasFromCollectingLists(); + } + + { + AutoLockHelperThreadState lock; + lifoBlocksToFree.ref().freeAll(); + } + + lastMarkSlice = false; + incrementalState = State::Finish; + +#ifdef DEBUG + for (auto& marker : markers) { + MOZ_ASSERT(!marker->shouldCheckCompartments()); + } +#endif + + break; + } + + case State::Sweep: { + // Finish sweeping the current sweep group, then abort. + for (CompartmentsIter c(rt); !c.done(); c.next()) { + c->gcState.scheduledForDestruction = false; + } + + abortSweepAfterCurrentGroup = true; + isCompacting = false; + + break; + } + + case State::Finalize: { + isCompacting = false; + break; + } + + case State::Compact: { + // Skip any remaining zones that would have been compacted. + MOZ_ASSERT(isCompacting); + startedCompacting = true; + zonesToMaybeCompact.ref().clear(); + break; + } + + case State::Decommit: { + break; + } + } + + stats().reset(reason); + + return IncrementalResult::ResetIncremental; +} + +AutoDisableBarriers::AutoDisableBarriers(GCRuntime* gc) : gc(gc) { + /* + * Clear needsIncrementalBarrier early so we don't do any write barriers + * during sweeping. + */ + for (GCZonesIter zone(gc); !zone.done(); zone.next()) { + if (zone->isGCMarking()) { + MOZ_ASSERT(zone->needsIncrementalBarrier()); + zone->setNeedsIncrementalBarrier(false); + } + MOZ_ASSERT(!zone->needsIncrementalBarrier()); + } +} + +AutoDisableBarriers::~AutoDisableBarriers() { + for (GCZonesIter zone(gc); !zone.done(); zone.next()) { + MOZ_ASSERT(!zone->needsIncrementalBarrier()); + if (zone->isGCMarking()) { + zone->setNeedsIncrementalBarrier(true); + } + } +} + +static bool NeedToCollectNursery(GCRuntime* gc) { + return !gc->nursery().isEmpty() || !gc->storeBuffer().isEmpty(); +} + +#ifdef DEBUG +static const char* DescribeBudget(const SliceBudget& budget) { + constexpr size_t length = 32; + static char buffer[length]; + budget.describe(buffer, length); + return buffer; +} +#endif + +static bool ShouldPauseMutatorWhileWaiting(const SliceBudget& budget, + JS::GCReason reason, + bool budgetWasIncreased) { + // When we're nearing the incremental limit at which we will finish the + // collection synchronously, pause the main thread if there is only background + // GC work happening. This allows the GC to catch up and avoid hitting the + // limit. + return budget.isTimeBudget() && + (reason == JS::GCReason::ALLOC_TRIGGER || + reason == JS::GCReason::TOO_MUCH_MALLOC) && + budgetWasIncreased; +} + +void GCRuntime::incrementalSlice(SliceBudget& budget, JS::GCReason reason, + bool budgetWasIncreased) { + MOZ_ASSERT_IF(isIncrementalGCInProgress(), isIncremental); + + AutoSetThreadIsPerformingGC performingGC(rt->gcContext()); + + AutoGCSession session(this, JS::HeapState::MajorCollecting); + + bool destroyingRuntime = (reason == JS::GCReason::DESTROY_RUNTIME); + + initialState = incrementalState; + isIncremental = !budget.isUnlimited(); + useBackgroundThreads = ShouldUseBackgroundThreads(isIncremental, reason); + haveDiscardedJITCodeThisSlice = false; + +#ifdef JS_GC_ZEAL + // Do the incremental collection type specified by zeal mode if the collection + // was triggered by runDebugGC() and incremental GC has not been cancelled by + // resetIncrementalGC(). + useZeal = isIncremental && reason == JS::GCReason::DEBUG_GC; +#endif + +#ifdef DEBUG + stats().log( + "Incremental: %d, lastMarkSlice: %d, useZeal: %d, budget: %s, " + "budgetWasIncreased: %d", + bool(isIncremental), bool(lastMarkSlice), bool(useZeal), + DescribeBudget(budget), budgetWasIncreased); +#endif + + if (useZeal && hasIncrementalTwoSliceZealMode()) { + // Yields between slices occurs at predetermined points in these modes; the + // budget is not used. |isIncremental| is still true. + stats().log("Using unlimited budget for two-slice zeal mode"); + budget = SliceBudget::unlimited(); + } + + bool shouldPauseMutator = + ShouldPauseMutatorWhileWaiting(budget, reason, budgetWasIncreased); + + switch (incrementalState) { + case State::NotActive: + startCollection(reason); + + incrementalState = State::Prepare; + if (!beginPreparePhase(reason, session)) { + incrementalState = State::NotActive; + break; + } + + if (useZeal && hasZealMode(ZealMode::YieldBeforeRootMarking)) { + break; + } + + [[fallthrough]]; + + case State::Prepare: + if (waitForBackgroundTask(unmarkTask, budget, shouldPauseMutator, + DontTriggerSliceWhenFinished) == NotFinished) { + break; + } + + incrementalState = State::MarkRoots; + [[fallthrough]]; + + case State::MarkRoots: + if (NeedToCollectNursery(this)) { + collectNurseryFromMajorGC(reason); + } + + endPreparePhase(reason); + beginMarkPhase(session); + incrementalState = State::Mark; + + if (useZeal && hasZealMode(ZealMode::YieldBeforeMarking) && + isIncremental) { + break; + } + + [[fallthrough]]; + + case State::Mark: + if (mightSweepInThisSlice(budget.isUnlimited())) { + // Trace wrapper rooters before marking if we might start sweeping in + // this slice. + rt->mainContextFromOwnThread()->traceWrapperGCRooters( + marker().tracer()); + } + + { + gcstats::AutoPhase ap(stats(), gcstats::PhaseKind::MARK); + if (markUntilBudgetExhausted(budget, useParallelMarking) == + NotFinished) { + break; + } + } + + assertNoMarkingWork(); + + /* + * There are a number of reasons why we break out of collection here, + * either ending the slice or to run a new interation of the loop in + * GCRuntime::collect() + */ + + /* + * In incremental GCs where we have already performed more than one + * slice we yield after marking with the aim of starting the sweep in + * the next slice, since the first slice of sweeping can be expensive. + * + * This is modified by the various zeal modes. We don't yield in + * YieldBeforeMarking mode and we always yield in YieldBeforeSweeping + * mode. + * + * We will need to mark anything new on the stack when we resume, so + * we stay in Mark state. + */ + if (isIncremental && !lastMarkSlice) { + if ((initialState == State::Mark && + !(useZeal && hasZealMode(ZealMode::YieldBeforeMarking))) || + (useZeal && hasZealMode(ZealMode::YieldBeforeSweeping))) { + lastMarkSlice = true; + stats().log("Yielding before starting sweeping"); + break; + } + } + + incrementalState = State::Sweep; + lastMarkSlice = false; + + beginSweepPhase(reason, session); + + [[fallthrough]]; + + case State::Sweep: + if (storeBuffer().mayHavePointersToDeadCells()) { + collectNurseryFromMajorGC(reason); + } + + if (initialState == State::Sweep) { + rt->mainContextFromOwnThread()->traceWrapperGCRooters( + marker().tracer()); + } + + if (performSweepActions(budget) == NotFinished) { + break; + } + + endSweepPhase(destroyingRuntime); + + incrementalState = State::Finalize; + + [[fallthrough]]; + + case State::Finalize: + if (waitForBackgroundTask(sweepTask, budget, shouldPauseMutator, + TriggerSliceWhenFinished) == NotFinished) { + break; + } + + assertBackgroundSweepingFinished(); + + { + // Sweep the zones list now that background finalization is finished to + // remove and free dead zones, compartments and realms. + gcstats::AutoPhase ap1(stats(), gcstats::PhaseKind::SWEEP); + gcstats::AutoPhase ap2(stats(), gcstats::PhaseKind::DESTROY); + sweepZones(rt->gcContext(), destroyingRuntime); + } + + MOZ_ASSERT(!startedCompacting); + incrementalState = State::Compact; + + // Always yield before compacting since it is not incremental. + if (isCompacting && !budget.isUnlimited()) { + break; + } + + [[fallthrough]]; + + case State::Compact: + if (isCompacting) { + if (NeedToCollectNursery(this)) { + collectNurseryFromMajorGC(reason); + } + + storeBuffer().checkEmpty(); + if (!startedCompacting) { + beginCompactPhase(); + } + + if (compactPhase(reason, budget, session) == NotFinished) { + break; + } + + endCompactPhase(); + } + + startDecommit(); + incrementalState = State::Decommit; + + [[fallthrough]]; + + case State::Decommit: + if (waitForBackgroundTask(decommitTask, budget, shouldPauseMutator, + TriggerSliceWhenFinished) == NotFinished) { + break; + } + + incrementalState = State::Finish; + + [[fallthrough]]; + + case State::Finish: + finishCollection(reason); + incrementalState = State::NotActive; + break; + } + +#ifdef DEBUG + MOZ_ASSERT(safeToYield); + for (auto& marker : markers) { + MOZ_ASSERT(marker->markColor() == MarkColor::Black); + } + MOZ_ASSERT(!rt->gcContext()->hasJitCodeToPoison()); +#endif +} + +void GCRuntime::collectNurseryFromMajorGC(JS::GCReason reason) { + collectNursery(gcOptions(), reason, + gcstats::PhaseKind::EVICT_NURSERY_FOR_MAJOR_GC); +} + +bool GCRuntime::hasForegroundWork() const { + switch (incrementalState) { + case State::NotActive: + // Incremental GC is not running and no work is pending. + return false; + case State::Prepare: + // We yield in the Prepare state after starting unmarking. + return !unmarkTask.wasStarted(); + case State::Finalize: + // We yield in the Finalize state to wait for background sweeping. + return !isBackgroundSweeping(); + case State::Decommit: + // We yield in the Decommit state to wait for background decommit. + return !decommitTask.wasStarted(); + default: + // In all other states there is still work to do. + return true; + } +} + +IncrementalProgress GCRuntime::waitForBackgroundTask( + GCParallelTask& task, const SliceBudget& budget, bool shouldPauseMutator, + ShouldTriggerSliceWhenFinished triggerSlice) { + // Wait here in non-incremental collections, or if we want to pause the + // mutator to let the GC catch up. + if (budget.isUnlimited() || shouldPauseMutator) { + gcstats::AutoPhase ap(stats(), gcstats::PhaseKind::WAIT_BACKGROUND_THREAD); + Maybe deadline; + if (budget.isTimeBudget()) { + deadline.emplace(budget.deadline()); + } + task.join(deadline); + } + + // In incremental collections, yield if the task has not finished and + // optionally request a slice to notify us when this happens. + if (!budget.isUnlimited()) { + AutoLockHelperThreadState lock; + if (task.wasStarted(lock)) { + if (triggerSlice) { + requestSliceAfterBackgroundTask = true; + } + return NotFinished; + } + + task.joinWithLockHeld(lock); + } + + MOZ_ASSERT(task.isIdle()); + + if (triggerSlice) { + cancelRequestedGCAfterBackgroundTask(); + } + + return Finished; +} + +GCAbortReason gc::IsIncrementalGCUnsafe(JSRuntime* rt) { + MOZ_ASSERT(!rt->mainContextFromOwnThread()->suppressGC); + + if (!rt->gc.isIncrementalGCAllowed()) { + return GCAbortReason::IncrementalDisabled; + } + + return GCAbortReason::None; +} + +inline void GCRuntime::checkZoneIsScheduled(Zone* zone, JS::GCReason reason, + const char* trigger) { +#ifdef DEBUG + if (zone->isGCScheduled()) { + return; + } + + fprintf(stderr, + "checkZoneIsScheduled: Zone %p not scheduled as expected in %s GC " + "for %s trigger\n", + zone, JS::ExplainGCReason(reason), trigger); + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + fprintf(stderr, " Zone %p:%s%s\n", zone.get(), + zone->isAtomsZone() ? " atoms" : "", + zone->isGCScheduled() ? " scheduled" : ""); + } + fflush(stderr); + MOZ_CRASH("Zone not scheduled"); +#endif +} + +GCRuntime::IncrementalResult GCRuntime::budgetIncrementalGC( + bool nonincrementalByAPI, JS::GCReason reason, SliceBudget& budget) { + if (nonincrementalByAPI) { + stats().nonincremental(GCAbortReason::NonIncrementalRequested); + budget = SliceBudget::unlimited(); + + // Reset any in progress incremental GC if this was triggered via the + // API. This isn't required for correctness, but sometimes during tests + // the caller expects this GC to collect certain objects, and we need + // to make sure to collect everything possible. + if (reason != JS::GCReason::ALLOC_TRIGGER) { + return resetIncrementalGC(GCAbortReason::NonIncrementalRequested); + } + + return IncrementalResult::Ok; + } + + if (reason == JS::GCReason::ABORT_GC) { + budget = SliceBudget::unlimited(); + stats().nonincremental(GCAbortReason::AbortRequested); + return resetIncrementalGC(GCAbortReason::AbortRequested); + } + + if (!budget.isUnlimited()) { + GCAbortReason unsafeReason = IsIncrementalGCUnsafe(rt); + if (unsafeReason == GCAbortReason::None) { + if (reason == JS::GCReason::COMPARTMENT_REVIVED) { + unsafeReason = GCAbortReason::CompartmentRevived; + } else if (!incrementalGCEnabled) { + unsafeReason = GCAbortReason::ModeChange; + } + } + + if (unsafeReason != GCAbortReason::None) { + budget = SliceBudget::unlimited(); + stats().nonincremental(unsafeReason); + return resetIncrementalGC(unsafeReason); + } + } + + GCAbortReason resetReason = GCAbortReason::None; + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + if (zone->gcHeapSize.bytes() >= + zone->gcHeapThreshold.incrementalLimitBytes()) { + checkZoneIsScheduled(zone, reason, "GC bytes"); + budget = SliceBudget::unlimited(); + stats().nonincremental(GCAbortReason::GCBytesTrigger); + if (zone->wasGCStarted() && zone->gcState() > Zone::Sweep) { + resetReason = GCAbortReason::GCBytesTrigger; + } + } + + if (zone->mallocHeapSize.bytes() >= + zone->mallocHeapThreshold.incrementalLimitBytes()) { + checkZoneIsScheduled(zone, reason, "malloc bytes"); + budget = SliceBudget::unlimited(); + stats().nonincremental(GCAbortReason::MallocBytesTrigger); + if (zone->wasGCStarted() && zone->gcState() > Zone::Sweep) { + resetReason = GCAbortReason::MallocBytesTrigger; + } + } + + if (zone->jitHeapSize.bytes() >= + zone->jitHeapThreshold.incrementalLimitBytes()) { + checkZoneIsScheduled(zone, reason, "JIT code bytes"); + budget = SliceBudget::unlimited(); + stats().nonincremental(GCAbortReason::JitCodeBytesTrigger); + if (zone->wasGCStarted() && zone->gcState() > Zone::Sweep) { + resetReason = GCAbortReason::JitCodeBytesTrigger; + } + } + + if (isIncrementalGCInProgress() && + zone->isGCScheduled() != zone->wasGCStarted()) { + budget = SliceBudget::unlimited(); + resetReason = GCAbortReason::ZoneChange; + } + } + + if (resetReason != GCAbortReason::None) { + return resetIncrementalGC(resetReason); + } + + return IncrementalResult::Ok; +} + +bool GCRuntime::maybeIncreaseSliceBudget(SliceBudget& budget) { + if (js::SupportDifferentialTesting()) { + return false; + } + + if (!budget.isTimeBudget() || !isIncrementalGCInProgress()) { + return false; + } + + bool wasIncreasedForLongCollections = + maybeIncreaseSliceBudgetForLongCollections(budget); + bool wasIncreasedForUgentCollections = + maybeIncreaseSliceBudgetForUrgentCollections(budget); + + return wasIncreasedForLongCollections || wasIncreasedForUgentCollections; +} + +// Return true if the budget is actually extended after rounding. +static bool ExtendBudget(SliceBudget& budget, double newDuration) { + long millis = lround(newDuration); + if (millis <= budget.timeBudget()) { + return false; + } + + bool idleTriggered = budget.idle; + budget = SliceBudget(TimeBudget(millis), nullptr); // Uninterruptible. + budget.idle = idleTriggered; + budget.extended = true; + return true; +} + +bool GCRuntime::maybeIncreaseSliceBudgetForLongCollections( + SliceBudget& budget) { + // For long-running collections, enforce a minimum time budget that increases + // linearly with time up to a maximum. + + // All times are in milliseconds. + struct BudgetAtTime { + double time; + double budget; + }; + const BudgetAtTime MinBudgetStart{1500, 0.0}; + const BudgetAtTime MinBudgetEnd{2500, 100.0}; + + double totalTime = (TimeStamp::Now() - lastGCStartTime()).ToMilliseconds(); + + double minBudget = + LinearInterpolate(totalTime, MinBudgetStart.time, MinBudgetStart.budget, + MinBudgetEnd.time, MinBudgetEnd.budget); + + return ExtendBudget(budget, minBudget); +} + +bool GCRuntime::maybeIncreaseSliceBudgetForUrgentCollections( + SliceBudget& budget) { + // Enforce a minimum time budget based on how close we are to the incremental + // limit. + + size_t minBytesRemaining = SIZE_MAX; + for (AllZonesIter zone(this); !zone.done(); zone.next()) { + if (!zone->wasGCStarted()) { + continue; + } + size_t gcBytesRemaining = + zone->gcHeapThreshold.incrementalBytesRemaining(zone->gcHeapSize); + minBytesRemaining = std::min(minBytesRemaining, gcBytesRemaining); + size_t mallocBytesRemaining = + zone->mallocHeapThreshold.incrementalBytesRemaining( + zone->mallocHeapSize); + minBytesRemaining = std::min(minBytesRemaining, mallocBytesRemaining); + } + + if (minBytesRemaining < tunables.urgentThresholdBytes() && + minBytesRemaining != 0) { + // Increase budget based on the reciprocal of the fraction remaining. + double fractionRemaining = + double(minBytesRemaining) / double(tunables.urgentThresholdBytes()); + double minBudget = double(defaultSliceBudgetMS()) / fractionRemaining; + return ExtendBudget(budget, minBudget); + } + + return false; +} + +static void ScheduleZones(GCRuntime* gc, JS::GCReason reason) { + for (ZonesIter zone(gc, WithAtoms); !zone.done(); zone.next()) { + // Re-check heap threshold for alloc-triggered zones that were not + // previously collected. Now we have allocation rate data, the heap limit + // may have been increased beyond the current size. + if (gc->tunables.balancedHeapLimitsEnabled() && zone->isGCScheduled() && + zone->smoothedCollectionRate.ref().isNothing() && + reason == JS::GCReason::ALLOC_TRIGGER && + zone->gcHeapSize.bytes() < zone->gcHeapThreshold.startBytes()) { + zone->unscheduleGC(); // May still be re-scheduled below. + } + + if (gc->isShutdownGC()) { + zone->scheduleGC(); + } + + if (!gc->isPerZoneGCEnabled()) { + zone->scheduleGC(); + } + + // To avoid resets, continue to collect any zones that were being + // collected in a previous slice. + if (gc->isIncrementalGCInProgress() && zone->wasGCStarted()) { + zone->scheduleGC(); + } + + // This is a heuristic to reduce the total number of collections. + bool inHighFrequencyMode = gc->schedulingState.inHighFrequencyGCMode(); + if (zone->gcHeapSize.bytes() >= + zone->gcHeapThreshold.eagerAllocTrigger(inHighFrequencyMode) || + zone->mallocHeapSize.bytes() >= + zone->mallocHeapThreshold.eagerAllocTrigger(inHighFrequencyMode) || + zone->jitHeapSize.bytes() >= zone->jitHeapThreshold.startBytes()) { + zone->scheduleGC(); + } + } +} + +static void UnscheduleZones(GCRuntime* gc) { + for (ZonesIter zone(gc->rt, WithAtoms); !zone.done(); zone.next()) { + zone->unscheduleGC(); + } +} + +class js::gc::AutoCallGCCallbacks { + GCRuntime& gc_; + JS::GCReason reason_; + + public: + explicit AutoCallGCCallbacks(GCRuntime& gc, JS::GCReason reason) + : gc_(gc), reason_(reason) { + gc_.maybeCallGCCallback(JSGC_BEGIN, reason); + } + ~AutoCallGCCallbacks() { gc_.maybeCallGCCallback(JSGC_END, reason_); } +}; + +void GCRuntime::maybeCallGCCallback(JSGCStatus status, JS::GCReason reason) { + if (!gcCallback.ref().op) { + return; + } + + if (isIncrementalGCInProgress()) { + return; + } + + if (gcCallbackDepth == 0) { + // Save scheduled zone information in case the callback clears it. + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + zone->gcScheduledSaved_ = zone->gcScheduled_; + } + } + + // Save and clear GC options and state in case the callback reenters GC. + JS::GCOptions options = gcOptions(); + maybeGcOptions = Nothing(); + bool savedFullGCRequested = fullGCRequested; + fullGCRequested = false; + + gcCallbackDepth++; + + callGCCallback(status, reason); + + MOZ_ASSERT(gcCallbackDepth != 0); + gcCallbackDepth--; + + // Restore the original GC options. + maybeGcOptions = Some(options); + + // At the end of a GC, clear out the fullGCRequested state. At the start, + // restore the previous setting. + fullGCRequested = (status == JSGC_END) ? false : savedFullGCRequested; + + if (gcCallbackDepth == 0) { + // Ensure any zone that was originally scheduled stays scheduled. + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + zone->gcScheduled_ = zone->gcScheduled_ || zone->gcScheduledSaved_; + } + } +} + +/* + * We disable inlining to ensure that the bottom of the stack with possible GC + * roots recorded in MarkRuntime excludes any pointers we use during the marking + * implementation. + */ +MOZ_NEVER_INLINE GCRuntime::IncrementalResult GCRuntime::gcCycle( + bool nonincrementalByAPI, const SliceBudget& budgetArg, + JS::GCReason reason) { + // Assert if this is a GC unsafe region. + rt->mainContextFromOwnThread()->verifyIsSafeToGC(); + + // It's ok if threads other than the main thread have suppressGC set, as + // they are operating on zones which will not be collected from here. + MOZ_ASSERT(!rt->mainContextFromOwnThread()->suppressGC); + + // This reason is used internally. See below. + MOZ_ASSERT(reason != JS::GCReason::RESET); + + // Background finalization and decommit are finished by definition before we + // can start a new major GC. Background allocation may still be running, but + // that's OK because chunk pools are protected by the GC lock. + if (!isIncrementalGCInProgress()) { + assertBackgroundSweepingFinished(); + MOZ_ASSERT(decommitTask.isIdle()); + } + + // Note that GC callbacks are allowed to re-enter GC. + AutoCallGCCallbacks callCallbacks(*this, reason); + + // Increase slice budget for long running collections before it is recorded by + // AutoGCSlice. + SliceBudget budget(budgetArg); + bool budgetWasIncreased = maybeIncreaseSliceBudget(budget); + + ScheduleZones(this, reason); + + auto updateCollectorTime = MakeScopeExit([&] { + if (const gcstats::Statistics::SliceData* slice = stats().lastSlice()) { + collectorTimeSinceAllocRateUpdate += slice->duration(); + } + }); + + gcstats::AutoGCSlice agc(stats(), scanZonesBeforeGC(), gcOptions(), budget, + reason, budgetWasIncreased); + + IncrementalResult result = + budgetIncrementalGC(nonincrementalByAPI, reason, budget); + if (result == IncrementalResult::ResetIncremental) { + if (incrementalState == State::NotActive) { + // The collection was reset and has finished. + return result; + } + + // The collection was reset but we must finish up some remaining work. + reason = JS::GCReason::RESET; + } + + majorGCTriggerReason = JS::GCReason::NO_REASON; + MOZ_ASSERT(!stats().hasTrigger()); + + incGcNumber(); + incGcSliceNumber(); + + gcprobes::MajorGCStart(); + incrementalSlice(budget, reason, budgetWasIncreased); + gcprobes::MajorGCEnd(); + + MOZ_ASSERT_IF(result == IncrementalResult::ResetIncremental, + !isIncrementalGCInProgress()); + return result; +} + +inline bool GCRuntime::mightSweepInThisSlice(bool nonIncremental) { + MOZ_ASSERT(incrementalState < State::Sweep); + return nonIncremental || lastMarkSlice || hasIncrementalTwoSliceZealMode(); +} + +#ifdef JS_GC_ZEAL +static bool IsDeterministicGCReason(JS::GCReason reason) { + switch (reason) { + case JS::GCReason::API: + case JS::GCReason::DESTROY_RUNTIME: + case JS::GCReason::LAST_DITCH: + case JS::GCReason::TOO_MUCH_MALLOC: + case JS::GCReason::TOO_MUCH_WASM_MEMORY: + case JS::GCReason::TOO_MUCH_JIT_CODE: + case JS::GCReason::ALLOC_TRIGGER: + case JS::GCReason::DEBUG_GC: + case JS::GCReason::CC_FORCED: + case JS::GCReason::SHUTDOWN_CC: + case JS::GCReason::ABORT_GC: + case JS::GCReason::DISABLE_GENERATIONAL_GC: + case JS::GCReason::FINISH_GC: + case JS::GCReason::PREPARE_FOR_TRACING: + return true; + + default: + return false; + } +} +#endif + +gcstats::ZoneGCStats GCRuntime::scanZonesBeforeGC() { + gcstats::ZoneGCStats zoneStats; + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + zoneStats.zoneCount++; + zoneStats.compartmentCount += zone->compartments().length(); + for (CompartmentsInZoneIter comp(zone); !comp.done(); comp.next()) { + zoneStats.realmCount += comp->realms().length(); + } + if (zone->isGCScheduled()) { + zoneStats.collectedZoneCount++; + zoneStats.collectedCompartmentCount += zone->compartments().length(); + } + } + + return zoneStats; +} + +// The GC can only clean up scheduledForDestruction realms that were marked live +// by a barrier (e.g. by RemapWrappers from a navigation event). It is also +// common to have realms held live because they are part of a cycle in gecko, +// e.g. involving the HTMLDocument wrapper. In this case, we need to run the +// CycleCollector in order to remove these edges before the realm can be freed. +void GCRuntime::maybeDoCycleCollection() { + const static float ExcessiveGrayRealms = 0.8f; + const static size_t LimitGrayRealms = 200; + + size_t realmsTotal = 0; + size_t realmsGray = 0; + for (RealmsIter realm(rt); !realm.done(); realm.next()) { + ++realmsTotal; + GlobalObject* global = realm->unsafeUnbarrieredMaybeGlobal(); + if (global && global->isMarkedGray()) { + ++realmsGray; + } + } + float grayFraction = float(realmsGray) / float(realmsTotal); + if (grayFraction > ExcessiveGrayRealms || realmsGray > LimitGrayRealms) { + callDoCycleCollectionCallback(rt->mainContextFromOwnThread()); + } +} + +void GCRuntime::checkCanCallAPI() { + MOZ_RELEASE_ASSERT(CurrentThreadCanAccessRuntime(rt)); + + /* If we attempt to invoke the GC while we are running in the GC, assert. */ + MOZ_RELEASE_ASSERT(!JS::RuntimeHeapIsBusy()); +} + +bool GCRuntime::checkIfGCAllowedInCurrentState(JS::GCReason reason) { + if (rt->mainContextFromOwnThread()->suppressGC) { + return false; + } + + // Only allow shutdown GCs when we're destroying the runtime. This keeps + // the GC callback from triggering a nested GC and resetting global state. + if (rt->isBeingDestroyed() && !isShutdownGC()) { + return false; + } + +#ifdef JS_GC_ZEAL + if (deterministicOnly && !IsDeterministicGCReason(reason)) { + return false; + } +#endif + + return true; +} + +bool GCRuntime::shouldRepeatForDeadZone(JS::GCReason reason) { + MOZ_ASSERT_IF(reason == JS::GCReason::COMPARTMENT_REVIVED, !isIncremental); + MOZ_ASSERT(!isIncrementalGCInProgress()); + + if (!isIncremental) { + return false; + } + + for (CompartmentsIter c(rt); !c.done(); c.next()) { + if (c->gcState.scheduledForDestruction) { + return true; + } + } + + return false; +} + +struct MOZ_RAII AutoSetZoneSliceThresholds { + explicit AutoSetZoneSliceThresholds(GCRuntime* gc) : gc(gc) { + // On entry, zones that are already collecting should have a slice threshold + // set. + for (ZonesIter zone(gc, WithAtoms); !zone.done(); zone.next()) { + MOZ_ASSERT(zone->wasGCStarted() == + zone->gcHeapThreshold.hasSliceThreshold()); + MOZ_ASSERT(zone->wasGCStarted() == + zone->mallocHeapThreshold.hasSliceThreshold()); + } + } + + ~AutoSetZoneSliceThresholds() { + // On exit, update the thresholds for all collecting zones. + bool waitingOnBGTask = gc->isWaitingOnBackgroundTask(); + for (ZonesIter zone(gc, WithAtoms); !zone.done(); zone.next()) { + if (zone->wasGCStarted()) { + zone->setGCSliceThresholds(*gc, waitingOnBGTask); + } else { + MOZ_ASSERT(!zone->gcHeapThreshold.hasSliceThreshold()); + MOZ_ASSERT(!zone->mallocHeapThreshold.hasSliceThreshold()); + } + } + } + + GCRuntime* gc; +}; + +void GCRuntime::collect(bool nonincrementalByAPI, const SliceBudget& budget, + JS::GCReason reason) { + TimeStamp startTime = TimeStamp::Now(); + auto timer = MakeScopeExit([&] { + if (Realm* realm = rt->mainContextFromOwnThread()->realm()) { + realm->timers.gcTime += TimeStamp::Now() - startTime; + } + }); + + auto clearGCOptions = MakeScopeExit([&] { + if (!isIncrementalGCInProgress()) { + maybeGcOptions = Nothing(); + } + }); + + MOZ_ASSERT(reason != JS::GCReason::NO_REASON); + + // Checks run for each request, even if we do not actually GC. + checkCanCallAPI(); + + // Check if we are allowed to GC at this time before proceeding. + if (!checkIfGCAllowedInCurrentState(reason)) { + return; + } + + stats().log("GC slice starting in state %s", StateName(incrementalState)); + + AutoStopVerifyingBarriers av(rt, isShutdownGC()); + AutoMaybeLeaveAtomsZone leaveAtomsZone(rt->mainContextFromOwnThread()); + AutoSetZoneSliceThresholds sliceThresholds(this); + + schedulingState.updateHighFrequencyModeForReason(reason); + + if (!isIncrementalGCInProgress() && tunables.balancedHeapLimitsEnabled()) { + updateAllocationRates(); + } + + bool repeat; + do { + IncrementalResult cycleResult = + gcCycle(nonincrementalByAPI, budget, reason); + + if (reason == JS::GCReason::ABORT_GC) { + MOZ_ASSERT(!isIncrementalGCInProgress()); + stats().log("GC aborted by request"); + break; + } + + /* + * Sometimes when we finish a GC we need to immediately start a new one. + * This happens in the following cases: + * - when we reset the current GC + * - when finalizers drop roots during shutdown + * - when zones that we thought were dead at the start of GC are + * not collected (see the large comment in beginMarkPhase) + */ + repeat = false; + if (!isIncrementalGCInProgress()) { + if (cycleResult == ResetIncremental) { + repeat = true; + } else if (rootsRemoved && isShutdownGC()) { + /* Need to re-schedule all zones for GC. */ + JS::PrepareForFullGC(rt->mainContextFromOwnThread()); + repeat = true; + reason = JS::GCReason::ROOTS_REMOVED; + } else if (shouldRepeatForDeadZone(reason)) { + repeat = true; + reason = JS::GCReason::COMPARTMENT_REVIVED; + } + } + } while (repeat); + + if (reason == JS::GCReason::COMPARTMENT_REVIVED) { + maybeDoCycleCollection(); + } + +#ifdef JS_GC_ZEAL + if (hasZealMode(ZealMode::CheckHeapAfterGC)) { + gcstats::AutoPhase ap(stats(), gcstats::PhaseKind::TRACE_HEAP); + CheckHeapAfterGC(rt); + } + if (hasZealMode(ZealMode::CheckGrayMarking) && !isIncrementalGCInProgress()) { + MOZ_RELEASE_ASSERT(CheckGrayMarkingState(rt)); + } +#endif + stats().log("GC slice ending in state %s", StateName(incrementalState)); + + UnscheduleZones(this); +} + +SliceBudget GCRuntime::defaultBudget(JS::GCReason reason, int64_t millis) { + // millis == 0 means use internal GC scheduling logic to come up with + // a duration for the slice budget. This may end up still being zero + // based on preferences. + if (millis == 0) { + millis = defaultSliceBudgetMS(); + } + + // If the embedding has registered a callback for creating SliceBudgets, + // then use it. + if (createBudgetCallback) { + return createBudgetCallback(reason, millis); + } + + // Otherwise, the preference can request an unlimited duration slice. + if (millis == 0) { + return SliceBudget::unlimited(); + } + + return SliceBudget(TimeBudget(millis)); +} + +void GCRuntime::gc(JS::GCOptions options, JS::GCReason reason) { + if (!isIncrementalGCInProgress()) { + setGCOptions(options); + } + + collect(true, SliceBudget::unlimited(), reason); +} + +void GCRuntime::startGC(JS::GCOptions options, JS::GCReason reason, + const js::SliceBudget& budget) { + MOZ_ASSERT(!isIncrementalGCInProgress()); + setGCOptions(options); + + if (!JS::IsIncrementalGCEnabled(rt->mainContextFromOwnThread())) { + collect(true, SliceBudget::unlimited(), reason); + return; + } + + collect(false, budget, reason); +} + +void GCRuntime::setGCOptions(JS::GCOptions options) { + MOZ_ASSERT(maybeGcOptions == Nothing()); + maybeGcOptions = Some(options); +} + +void GCRuntime::gcSlice(JS::GCReason reason, const js::SliceBudget& budget) { + MOZ_ASSERT(isIncrementalGCInProgress()); + collect(false, budget, reason); +} + +void GCRuntime::finishGC(JS::GCReason reason) { + MOZ_ASSERT(isIncrementalGCInProgress()); + + // If we're not collecting because we're out of memory then skip the + // compacting phase if we need to finish an ongoing incremental GC + // non-incrementally to avoid janking the browser. + if (!IsOOMReason(initialReason)) { + if (incrementalState == State::Compact) { + abortGC(); + return; + } + + isCompacting = false; + } + + collect(false, SliceBudget::unlimited(), reason); +} + +void GCRuntime::abortGC() { + MOZ_ASSERT(isIncrementalGCInProgress()); + checkCanCallAPI(); + MOZ_ASSERT(!rt->mainContextFromOwnThread()->suppressGC); + + collect(false, SliceBudget::unlimited(), JS::GCReason::ABORT_GC); +} + +static bool ZonesSelected(GCRuntime* gc) { + for (ZonesIter zone(gc, WithAtoms); !zone.done(); zone.next()) { + if (zone->isGCScheduled()) { + return true; + } + } + return false; +} + +void GCRuntime::startDebugGC(JS::GCOptions options, const SliceBudget& budget) { + MOZ_ASSERT(!isIncrementalGCInProgress()); + setGCOptions(options); + + if (!ZonesSelected(this)) { + JS::PrepareForFullGC(rt->mainContextFromOwnThread()); + } + + collect(false, budget, JS::GCReason::DEBUG_GC); +} + +void GCRuntime::debugGCSlice(const SliceBudget& budget) { + MOZ_ASSERT(isIncrementalGCInProgress()); + + if (!ZonesSelected(this)) { + JS::PrepareForIncrementalGC(rt->mainContextFromOwnThread()); + } + + collect(false, budget, JS::GCReason::DEBUG_GC); +} + +/* Schedule a full GC unless a zone will already be collected. */ +void js::PrepareForDebugGC(JSRuntime* rt) { + if (!ZonesSelected(&rt->gc)) { + JS::PrepareForFullGC(rt->mainContextFromOwnThread()); + } +} + +void GCRuntime::onOutOfMallocMemory() { + // Stop allocating new chunks. + allocTask.cancelAndWait(); + + // Make sure we release anything queued for release. + decommitTask.join(); + nursery().joinDecommitTask(); + + // Wait for background free of nursery huge slots to finish. + sweepTask.join(); + + AutoLockGC lock(this); + onOutOfMallocMemory(lock); +} + +void GCRuntime::onOutOfMallocMemory(const AutoLockGC& lock) { +#ifdef DEBUG + // Release any relocated arenas we may be holding on to, without releasing + // the GC lock. + releaseHeldRelocatedArenasWithoutUnlocking(lock); +#endif + + // Throw away any excess chunks we have lying around. + freeEmptyChunks(lock); + + // Immediately decommit as many arenas as possible in the hopes that this + // might let the OS scrape together enough pages to satisfy the failing + // malloc request. + if (DecommitEnabled()) { + decommitFreeArenasWithoutUnlocking(lock); + } +} + +void GCRuntime::minorGC(JS::GCReason reason, gcstats::PhaseKind phase) { + MOZ_ASSERT(!JS::RuntimeHeapIsBusy()); + + MOZ_ASSERT_IF(reason == JS::GCReason::EVICT_NURSERY, + !rt->mainContextFromOwnThread()->suppressGC); + if (rt->mainContextFromOwnThread()->suppressGC) { + return; + } + + incGcNumber(); + + collectNursery(JS::GCOptions::Normal, reason, phase); + +#ifdef JS_GC_ZEAL + if (hasZealMode(ZealMode::CheckHeapAfterGC)) { + gcstats::AutoPhase ap(stats(), phase); + CheckHeapAfterGC(rt); + } +#endif + + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + maybeTriggerGCAfterAlloc(zone); + maybeTriggerGCAfterMalloc(zone); + } +} + +void GCRuntime::collectNursery(JS::GCOptions options, JS::GCReason reason, + gcstats::PhaseKind phase) { + AutoMaybeLeaveAtomsZone leaveAtomsZone(rt->mainContextFromOwnThread()); + + uint32_t numAllocs = 0; + for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) { + numAllocs += zone->getAndResetTenuredAllocsSinceMinorGC(); + } + stats().setAllocsSinceMinorGCTenured(numAllocs); + + gcstats::AutoPhase ap(stats(), phase); + + nursery().collect(options, reason); + MOZ_ASSERT(nursery().isEmpty()); + + startBackgroundFreeAfterMinorGC(); +} + +void GCRuntime::startBackgroundFreeAfterMinorGC() { + MOZ_ASSERT(nursery().isEmpty()); + + { + AutoLockHelperThreadState lock; + + lifoBlocksToFree.ref().transferFrom(&lifoBlocksToFreeAfterMinorGC.ref()); + + if (lifoBlocksToFree.ref().isEmpty() && + buffersToFreeAfterMinorGC.ref().empty()) { + return; + } + } + + startBackgroundFree(); +} + +bool GCRuntime::gcIfRequestedImpl(bool eagerOk) { + // This method returns whether a major GC was performed. + + if (nursery().minorGCRequested()) { + minorGC(nursery().minorGCTriggerReason()); + } + + JS::GCReason reason = wantMajorGC(eagerOk); + if (reason == JS::GCReason::NO_REASON) { + return false; + } + + SliceBudget budget = defaultBudget(reason, 0); + if (!isIncrementalGCInProgress()) { + startGC(JS::GCOptions::Normal, reason, budget); + } else { + gcSlice(reason, budget); + } + return true; +} + +void js::gc::FinishGC(JSContext* cx, JS::GCReason reason) { + // Calling this when GC is suppressed won't have any effect. + MOZ_ASSERT(!cx->suppressGC); + + // GC callbacks may run arbitrary code, including JS. Check this regardless of + // whether we GC for this invocation. + MOZ_ASSERT(cx->isNurseryAllocAllowed()); + + if (JS::IsIncrementalGCInProgress(cx)) { + JS::PrepareForIncrementalGC(cx); + JS::FinishIncrementalGC(cx, reason); + } +} + +void js::gc::WaitForBackgroundTasks(JSContext* cx) { + cx->runtime()->gc.waitForBackgroundTasks(); +} + +void GCRuntime::waitForBackgroundTasks() { + MOZ_ASSERT(!isIncrementalGCInProgress()); + MOZ_ASSERT(sweepTask.isIdle()); + MOZ_ASSERT(decommitTask.isIdle()); + MOZ_ASSERT(markTask.isIdle()); + + allocTask.join(); + freeTask.join(); + nursery().joinDecommitTask(); +} + +Realm* js::NewRealm(JSContext* cx, JSPrincipals* principals, + const JS::RealmOptions& options) { + JSRuntime* rt = cx->runtime(); + JS_AbortIfWrongThread(cx); + + UniquePtr zoneHolder; + UniquePtr compHolder; + + Compartment* comp = nullptr; + Zone* zone = nullptr; + JS::CompartmentSpecifier compSpec = + options.creationOptions().compartmentSpecifier(); + switch (compSpec) { + case JS::CompartmentSpecifier::NewCompartmentInSystemZone: + // systemZone might be null here, in which case we'll make a zone and + // set this field below. + zone = rt->gc.systemZone; + break; + case JS::CompartmentSpecifier::NewCompartmentInExistingZone: + zone = options.creationOptions().zone(); + MOZ_ASSERT(zone); + break; + case JS::CompartmentSpecifier::ExistingCompartment: + comp = options.creationOptions().compartment(); + zone = comp->zone(); + break; + case JS::CompartmentSpecifier::NewCompartmentAndZone: + break; + } + + if (!zone) { + Zone::Kind kind = Zone::NormalZone; + const JSPrincipals* trusted = rt->trustedPrincipals(); + if (compSpec == JS::CompartmentSpecifier::NewCompartmentInSystemZone || + (principals && principals == trusted)) { + kind = Zone::SystemZone; + } + + zoneHolder = MakeUnique(cx->runtime(), kind); + if (!zoneHolder || !zoneHolder->init()) { + ReportOutOfMemory(cx); + return nullptr; + } + + zone = zoneHolder.get(); + } + + bool invisibleToDebugger = options.creationOptions().invisibleToDebugger(); + if (comp) { + // Debugger visibility is per-compartment, not per-realm, so make sure the + // new realm's visibility matches its compartment's. + MOZ_ASSERT(comp->invisibleToDebugger() == invisibleToDebugger); + } else { + compHolder = cx->make_unique(zone, invisibleToDebugger); + if (!compHolder) { + return nullptr; + } + + comp = compHolder.get(); + } + + UniquePtr realm(cx->new_(comp, options)); + if (!realm) { + return nullptr; + } + realm->init(cx, principals); + + // Make sure we don't put system and non-system realms in the same + // compartment. + if (!compHolder) { + MOZ_RELEASE_ASSERT(realm->isSystem() == IsSystemCompartment(comp)); + } + + AutoLockGC lock(rt); + + // Reserve space in the Vectors before we start mutating them. + if (!comp->realms().reserve(comp->realms().length() + 1) || + (compHolder && + !zone->compartments().reserve(zone->compartments().length() + 1)) || + (zoneHolder && !rt->gc.zones().reserve(rt->gc.zones().length() + 1))) { + ReportOutOfMemory(cx); + return nullptr; + } + + // After this everything must be infallible. + + comp->realms().infallibleAppend(realm.get()); + + if (compHolder) { + zone->compartments().infallibleAppend(compHolder.release()); + } + + if (zoneHolder) { + rt->gc.zones().infallibleAppend(zoneHolder.release()); + + // Lazily set the runtime's system zone. + if (compSpec == JS::CompartmentSpecifier::NewCompartmentInSystemZone) { + MOZ_RELEASE_ASSERT(!rt->gc.systemZone); + MOZ_ASSERT(zone->isSystemZone()); + rt->gc.systemZone = zone; + } + } + + return realm.release(); +} + +void GCRuntime::runDebugGC() { +#ifdef JS_GC_ZEAL + if (rt->mainContextFromOwnThread()->suppressGC) { + return; + } + + if (hasZealMode(ZealMode::GenerationalGC)) { + return minorGC(JS::GCReason::DEBUG_GC); + } + + PrepareForDebugGC(rt); + + auto budget = SliceBudget::unlimited(); + if (hasZealMode(ZealMode::IncrementalMultipleSlices)) { + /* + * Start with a small slice limit and double it every slice. This + * ensure that we get multiple slices, and collection runs to + * completion. + */ + if (!isIncrementalGCInProgress()) { + zealSliceBudget = zealFrequency / 2; + } else { + zealSliceBudget *= 2; + } + budget = SliceBudget(WorkBudget(zealSliceBudget)); + + js::gc::State initialState = incrementalState; + if (!isIncrementalGCInProgress()) { + setGCOptions(JS::GCOptions::Shrink); + } + collect(false, budget, JS::GCReason::DEBUG_GC); + + /* Reset the slice size when we get to the sweep or compact phases. */ + if ((initialState == State::Mark && incrementalState == State::Sweep) || + (initialState == State::Sweep && incrementalState == State::Compact)) { + zealSliceBudget = zealFrequency / 2; + } + } else if (hasIncrementalTwoSliceZealMode()) { + // These modes trigger incremental GC that happens in two slices and the + // supplied budget is ignored by incrementalSlice. + budget = SliceBudget(WorkBudget(1)); + + if (!isIncrementalGCInProgress()) { + setGCOptions(JS::GCOptions::Normal); + } + collect(false, budget, JS::GCReason::DEBUG_GC); + } else if (hasZealMode(ZealMode::Compact)) { + gc(JS::GCOptions::Shrink, JS::GCReason::DEBUG_GC); + } else { + gc(JS::GCOptions::Normal, JS::GCReason::DEBUG_GC); + } + +#endif +} + +void GCRuntime::setFullCompartmentChecks(bool enabled) { + MOZ_ASSERT(!JS::RuntimeHeapIsMajorCollecting()); + fullCompartmentChecks = enabled; +} + +void GCRuntime::notifyRootsRemoved() { + rootsRemoved = true; + +#ifdef JS_GC_ZEAL + /* Schedule a GC to happen "soon". */ + if (hasZealMode(ZealMode::RootsChange)) { + nextScheduled = 1; + } +#endif +} + +#ifdef JS_GC_ZEAL +bool GCRuntime::selectForMarking(JSObject* object) { + MOZ_ASSERT(!JS::RuntimeHeapIsMajorCollecting()); + return selectedForMarking.ref().get().append(object); +} + +void GCRuntime::clearSelectedForMarking() { + selectedForMarking.ref().get().clearAndFree(); +} + +void GCRuntime::setDeterministic(bool enabled) { + MOZ_ASSERT(!JS::RuntimeHeapIsMajorCollecting()); + deterministicOnly = enabled; +} +#endif + +#ifdef DEBUG + +AutoAssertNoNurseryAlloc::AutoAssertNoNurseryAlloc() { + TlsContext.get()->disallowNurseryAlloc(); +} + +AutoAssertNoNurseryAlloc::~AutoAssertNoNurseryAlloc() { + TlsContext.get()->allowNurseryAlloc(); +} + +#endif // DEBUG + +#ifdef JSGC_HASH_TABLE_CHECKS +void GCRuntime::checkHashTablesAfterMovingGC() { + /* + * Check that internal hash tables no longer have any pointers to things + * that have been moved. + */ + rt->geckoProfiler().checkStringsMapAfterMovingGC(); + if (rt->hasJitRuntime() && rt->jitRuntime()->hasInterpreterEntryMap()) { + rt->jitRuntime()->getInterpreterEntryMap()->checkScriptsAfterMovingGC(); + } + for (ZonesIter zone(this, SkipAtoms); !zone.done(); zone.next()) { + zone->checkUniqueIdTableAfterMovingGC(); + zone->shapeZone().checkTablesAfterMovingGC(); + zone->checkAllCrossCompartmentWrappersAfterMovingGC(); + zone->checkScriptMapsAfterMovingGC(); + + // Note: CompactPropMaps never have a table. + JS::AutoCheckCannotGC nogc; + for (auto map = zone->cellIterUnsafe(); !map.done(); + map.next()) { + if (PropMapTable* table = map->asLinked()->maybeTable(nogc)) { + table->checkAfterMovingGC(); + } + } + for (auto map = zone->cellIterUnsafe(); !map.done(); + map.next()) { + if (PropMapTable* table = map->asLinked()->maybeTable(nogc)) { + table->checkAfterMovingGC(); + } + } + } + + for (CompartmentsIter c(this); !c.done(); c.next()) { + for (RealmsInCompartmentIter r(c); !r.done(); r.next()) { + r->dtoaCache.checkCacheAfterMovingGC(); + if (r->debugEnvs()) { + r->debugEnvs()->checkHashTablesAfterMovingGC(); + } + } + } +} +#endif + +#ifdef DEBUG +bool GCRuntime::hasZone(Zone* target) { + for (AllZonesIter zone(this); !zone.done(); zone.next()) { + if (zone == target) { + return true; + } + } + return false; +} +#endif + +void AutoAssertEmptyNursery::checkCondition(JSContext* cx) { + if (!noAlloc) { + noAlloc.emplace(); + } + this->cx = cx; + MOZ_ASSERT(cx->nursery().isEmpty()); +} + +AutoEmptyNursery::AutoEmptyNursery(JSContext* cx) { + MOZ_ASSERT(!cx->suppressGC); + cx->runtime()->gc.stats().suspendPhases(); + cx->runtime()->gc.evictNursery(JS::GCReason::EVICT_NURSERY); + cx->runtime()->gc.stats().resumePhases(); + checkCondition(cx); +} + +#ifdef DEBUG + +namespace js { + +// We don't want jsfriendapi.h to depend on GenericPrinter, +// so these functions are declared directly in the cpp. + +extern JS_PUBLIC_API void DumpString(JSString* str, js::GenericPrinter& out); + +} // namespace js + +void js::gc::Cell::dump(js::GenericPrinter& out) const { + switch (getTraceKind()) { + case JS::TraceKind::Object: + reinterpret_cast(this)->dump(out); + break; + + case JS::TraceKind::String: + js::DumpString(reinterpret_cast(const_cast(this)), out); + break; + + case JS::TraceKind::Shape: + reinterpret_cast(this)->dump(out); + break; + + default: + out.printf("%s(%p)\n", JS::GCTraceKindToAscii(getTraceKind()), + (void*)this); + } +} + +// For use in a debugger. +void js::gc::Cell::dump() const { + js::Fprinter out(stderr); + dump(out); +} +#endif + +JS_PUBLIC_API bool js::gc::detail::CanCheckGrayBits(const TenuredCell* cell) { + // We do not check the gray marking state of cells in the following cases: + // + // 1) When OOM has caused us to clear the gcGrayBitsValid_ flag. + // + // 2) When we are in an incremental GC and examine a cell that is in a zone + // that is not being collected. Gray targets of CCWs that are marked black + // by a barrier will eventually be marked black in a later GC slice. + // + // 3) When mark bits are being cleared concurrently by a helper thread. + + MOZ_ASSERT(cell); + + auto* runtime = cell->runtimeFromAnyThread(); + MOZ_ASSERT(CurrentThreadCanAccessRuntime(runtime)); + + if (!runtime->gc.areGrayBitsValid()) { + return false; + } + + JS::Zone* zone = cell->zone(); + + if (runtime->gc.isIncrementalGCInProgress() && !zone->wasGCStarted()) { + return false; + } + + return !zone->isGCPreparing(); +} + +JS_PUBLIC_API bool js::gc::detail::CellIsMarkedGrayIfKnown( + const TenuredCell* cell) { + MOZ_ASSERT_IF(cell->isPermanentAndMayBeShared(), cell->isMarkedBlack()); + if (!cell->isMarkedGray()) { + return false; + } + + return CanCheckGrayBits(cell); +} + +#ifdef DEBUG + +JS_PUBLIC_API void js::gc::detail::AssertCellIsNotGray(const Cell* cell) { + if (!cell->isTenured()) { + return; + } + + // Check that a cell is not marked gray. + // + // Since this is a debug-only check, take account of the eventual mark state + // of cells that will be marked black by the next GC slice in an incremental + // GC. For performance reasons we don't do this in CellIsMarkedGrayIfKnown. + + const auto* tc = &cell->asTenured(); + if (!tc->isMarkedGray() || !CanCheckGrayBits(tc)) { + return; + } + + // TODO: I'd like to AssertHeapIsIdle() here, but this ends up getting + // called during GC and while iterating the heap for memory reporting. + MOZ_ASSERT(!JS::RuntimeHeapIsCycleCollecting()); + + if (tc->zone()->isGCMarkingBlackAndGray()) { + // We are doing gray marking in the cell's zone. Even if the cell is + // currently marked gray it may eventually be marked black. Delay checking + // non-black cells until we finish gray marking. + + if (!tc->isMarkedBlack()) { + JSRuntime* rt = tc->zone()->runtimeFromMainThread(); + AutoEnterOOMUnsafeRegion oomUnsafe; + if (!rt->gc.cellsToAssertNotGray.ref().append(cell)) { + oomUnsafe.crash("Can't append to delayed gray checks list"); + } + } + return; + } + + MOZ_ASSERT(!tc->isMarkedGray()); +} + +extern JS_PUBLIC_API bool js::gc::detail::ObjectIsMarkedBlack( + const JSObject* obj) { + return obj->isMarkedBlack(); +} + +#endif + +js::gc::ClearEdgesTracer::ClearEdgesTracer(JSRuntime* rt) + : GenericTracerImpl(rt, JS::TracerKind::ClearEdges, + JS::WeakMapTraceAction::TraceKeysAndValues) {} + +template +void js::gc::ClearEdgesTracer::onEdge(T** thingp, const char* name) { + // We don't handle removing pointers to nursery edges from the store buffer + // with this tracer. Check that this doesn't happen. + T* thing = *thingp; + MOZ_ASSERT(!IsInsideNursery(thing)); + + // Fire the pre-barrier since we're removing an edge from the graph. + InternalBarrierMethods::preBarrier(thing); + + *thingp = nullptr; +} + +void GCRuntime::setPerformanceHint(PerformanceHint hint) { + if (hint == PerformanceHint::InPageLoad) { + inPageLoadCount++; + } else { + MOZ_ASSERT(inPageLoadCount); + inPageLoadCount--; + } +} -- cgit v1.2.3