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|
/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
* vim: set ts=8 sts=2 et sw=2 tw=80:
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#include "mozilla/DebugOnly.h"
#include "mozilla/IntegerPrintfMacros.h"
#include "mozilla/Sprintf.h"
#include <algorithm>
#include <utility>
#ifdef MOZ_VALGRIND
# include <valgrind/memcheck.h>
#endif
#include "gc/GCInternals.h"
#include "gc/GCLock.h"
#include "gc/PublicIterators.h"
#include "gc/WeakMap.h"
#include "gc/Zone.h"
#include "js/friend/DumpFunctions.h" // js::DumpObject
#include "js/HashTable.h"
#include "vm/JSContext.h"
#include "gc/ArenaList-inl.h"
#include "gc/GC-inl.h"
#include "gc/Marking-inl.h"
#include "gc/PrivateIterators-inl.h"
#include "vm/JSContext-inl.h"
using namespace js;
using namespace js::gc;
using mozilla::DebugOnly;
#ifdef DEBUG
bool js::RuntimeIsVerifyingPreBarriers(JSRuntime* runtime) {
# ifdef JS_GC_ZEAL
return runtime->gc.isVerifyPreBarriersEnabled();
# else
return false;
# endif
}
#endif
#ifdef JS_GC_ZEAL
/*
* Write barrier verification
*
* The next few functions are for write barrier verification.
*
* The VerifyBarriers function is a shorthand. It checks if a verification phase
* is currently running. If not, it starts one. Otherwise, it ends the current
* phase and starts a new one.
*
* The user can adjust the frequency of verifications, which causes
* VerifyBarriers to be a no-op all but one out of N calls. However, if the
* |always| parameter is true, it starts a new phase no matter what.
*
* Pre-Barrier Verifier:
* When StartVerifyBarriers is called, a snapshot is taken of all objects in
* the GC heap and saved in an explicit graph data structure. Later,
* EndVerifyBarriers traverses the heap again. Any pointer values that were in
* the snapshot and are no longer found must be marked; otherwise an assertion
* triggers. Note that we must not GC in between starting and finishing a
* verification phase.
*/
struct EdgeValue {
JS::GCCellPtr thing;
const char* label;
};
struct VerifyNode {
JS::GCCellPtr thing;
uint32_t count;
EdgeValue edges[1];
};
typedef HashMap<Cell*, VerifyNode*, DefaultHasher<Cell*>, SystemAllocPolicy>
NodeMap;
/*
* The verifier data structures are simple. The entire graph is stored in a
* single block of memory. At the beginning is a VerifyNode for the root
* node. It is followed by a sequence of EdgeValues--the exact number is given
* in the node. After the edges come more nodes and their edges.
*
* The edgeptr and term fields are used to allocate out of the block of memory
* for the graph. If we run out of memory (i.e., if edgeptr goes beyond term),
* we just abandon the verification.
*
* The nodemap field is a hashtable that maps from the address of the GC thing
* to the VerifyNode that represents it.
*/
class js::VerifyPreTracer final : public JS::CallbackTracer {
JS::AutoDisableGenerationalGC noggc;
void onChild(const JS::GCCellPtr& thing) override;
public:
/* The gcNumber when the verification began. */
uint64_t number;
/* This counts up to gcZealFrequency to decide whether to verify. */
int count;
/* This graph represents the initial GC "snapshot". */
VerifyNode* curnode;
VerifyNode* root;
char* edgeptr;
char* term;
NodeMap nodemap;
explicit VerifyPreTracer(JSRuntime* rt)
: JS::CallbackTracer(rt, JS::TracerKind::Callback,
JS::WeakEdgeTraceAction::Skip),
noggc(rt->mainContextFromOwnThread()),
number(rt->gc.gcNumber()),
count(0),
curnode(nullptr),
root(nullptr),
edgeptr(nullptr),
term(nullptr) {
// We don't care about weak edges here. Since they are not marked they
// cannot cause the problem that the pre-write barrier protects against.
}
~VerifyPreTracer() { js_free(root); }
};
/*
* This function builds up the heap snapshot by adding edges to the current
* node.
*/
void VerifyPreTracer::onChild(const JS::GCCellPtr& thing) {
MOZ_ASSERT(!IsInsideNursery(thing.asCell()));
// Skip things in other runtimes.
if (thing.asCell()->asTenured().runtimeFromAnyThread() != runtime()) {
return;
}
edgeptr += sizeof(EdgeValue);
if (edgeptr >= term) {
edgeptr = term;
return;
}
VerifyNode* node = curnode;
uint32_t i = node->count;
node->edges[i].thing = thing;
node->edges[i].label = context().name();
node->count++;
}
static VerifyNode* MakeNode(VerifyPreTracer* trc, JS::GCCellPtr thing) {
NodeMap::AddPtr p = trc->nodemap.lookupForAdd(thing.asCell());
if (!p) {
VerifyNode* node = (VerifyNode*)trc->edgeptr;
trc->edgeptr += sizeof(VerifyNode) - sizeof(EdgeValue);
if (trc->edgeptr >= trc->term) {
trc->edgeptr = trc->term;
return nullptr;
}
node->thing = thing;
node->count = 0;
if (!trc->nodemap.add(p, thing.asCell(), node)) {
trc->edgeptr = trc->term;
return nullptr;
}
return node;
}
return nullptr;
}
static VerifyNode* NextNode(VerifyNode* node) {
if (node->count == 0) {
return (VerifyNode*)((char*)node + sizeof(VerifyNode) - sizeof(EdgeValue));
} else {
return (VerifyNode*)((char*)node + sizeof(VerifyNode) +
sizeof(EdgeValue) * (node->count - 1));
}
}
void gc::GCRuntime::startVerifyPreBarriers() {
if (verifyPreData || isIncrementalGCInProgress()) {
return;
}
JSContext* cx = rt->mainContextFromOwnThread();
if (IsIncrementalGCUnsafe(rt) != GCAbortReason::None ||
rt->hasHelperThreadZones()) {
return;
}
number++;
VerifyPreTracer* trc = js_new<VerifyPreTracer>(rt);
if (!trc) {
return;
}
AutoPrepareForTracing prep(cx);
{
AutoLockGC lock(this);
for (auto chunk = allNonEmptyChunks(lock); !chunk.done(); chunk.next()) {
chunk->markBits.clear();
}
}
gcstats::AutoPhase ap(stats(), gcstats::PhaseKind::TRACE_HEAP);
const size_t size = 64 * 1024 * 1024;
trc->root = (VerifyNode*)js_malloc(size);
if (!trc->root) {
goto oom;
}
trc->edgeptr = (char*)trc->root;
trc->term = trc->edgeptr + size;
/* Create the root node. */
trc->curnode = MakeNode(trc, JS::GCCellPtr());
MOZ_ASSERT(incrementalState == State::NotActive);
incrementalState = State::MarkRoots;
/* Make all the roots be edges emanating from the root node. */
traceRuntime(trc, prep);
VerifyNode* node;
node = trc->curnode;
if (trc->edgeptr == trc->term) {
goto oom;
}
/* For each edge, make a node for it if one doesn't already exist. */
while ((char*)node < trc->edgeptr) {
for (uint32_t i = 0; i < node->count; i++) {
EdgeValue& e = node->edges[i];
VerifyNode* child = MakeNode(trc, e.thing);
if (child) {
trc->curnode = child;
JS::TraceChildren(trc, e.thing);
}
if (trc->edgeptr == trc->term) {
goto oom;
}
}
node = NextNode(node);
}
verifyPreData = trc;
incrementalState = State::Mark;
marker.start();
for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) {
MOZ_ASSERT(!zone->usedByHelperThread());
zone->setNeedsIncrementalBarrier(true);
zone->arenas.clearFreeLists();
}
return;
oom:
incrementalState = State::NotActive;
js_delete(trc);
verifyPreData = nullptr;
}
static bool IsMarkedOrAllocated(TenuredCell* cell) {
return cell->isMarkedAny();
}
struct CheckEdgeTracer final : public JS::CallbackTracer {
VerifyNode* node;
explicit CheckEdgeTracer(JSRuntime* rt)
: JS::CallbackTracer(rt), node(nullptr) {}
void onChild(const JS::GCCellPtr& thing) override;
};
static const uint32_t MAX_VERIFIER_EDGES = 1000;
/*
* This function is called by EndVerifyBarriers for every heap edge. If the edge
* already existed in the original snapshot, we "cancel it out" by overwriting
* it with nullptr. EndVerifyBarriers later asserts that the remaining
* non-nullptr edges (i.e., the ones from the original snapshot that must have
* been modified) must point to marked objects.
*/
void CheckEdgeTracer::onChild(const JS::GCCellPtr& thing) {
// Skip things in other runtimes.
if (thing.asCell()->asTenured().runtimeFromAnyThread() != runtime()) {
return;
}
/* Avoid n^2 behavior. */
if (node->count > MAX_VERIFIER_EDGES) {
return;
}
for (uint32_t i = 0; i < node->count; i++) {
if (node->edges[i].thing == thing) {
node->edges[i].thing = JS::GCCellPtr();
return;
}
}
}
static bool IsMarkedOrAllocated(const EdgeValue& edge) {
if (!edge.thing || IsMarkedOrAllocated(&edge.thing.asCell()->asTenured())) {
return true;
}
// Permanent atoms and well-known symbols aren't marked during graph
// traversal.
if (edge.thing.is<JSString>() &&
edge.thing.as<JSString>().isPermanentAtom()) {
return true;
}
if (edge.thing.is<JS::Symbol>() &&
edge.thing.as<JS::Symbol>().isWellKnownSymbol()) {
return true;
}
return false;
}
void gc::GCRuntime::endVerifyPreBarriers() {
VerifyPreTracer* trc = verifyPreData;
if (!trc) {
return;
}
MOZ_ASSERT(!JS::IsGenerationalGCEnabled(rt));
AutoPrepareForTracing prep(rt->mainContextFromOwnThread());
bool compartmentCreated = false;
/* We need to disable barriers before tracing, which may invoke barriers. */
for (ZonesIter zone(this, WithAtoms); !zone.done(); zone.next()) {
if (!zone->needsIncrementalBarrier()) {
compartmentCreated = true;
}
zone->setNeedsIncrementalBarrier(false);
}
verifyPreData = nullptr;
MOZ_ASSERT(incrementalState == State::Mark);
incrementalState = State::NotActive;
if (!compartmentCreated && IsIncrementalGCUnsafe(rt) == GCAbortReason::None &&
!rt->hasHelperThreadZones()) {
CheckEdgeTracer cetrc(rt);
/* Start after the roots. */
VerifyNode* node = NextNode(trc->root);
while ((char*)node < trc->edgeptr) {
cetrc.node = node;
JS::TraceChildren(&cetrc, node->thing);
if (node->count <= MAX_VERIFIER_EDGES) {
for (uint32_t i = 0; i < node->count; i++) {
EdgeValue& edge = node->edges[i];
if (!IsMarkedOrAllocated(edge)) {
char msgbuf[1024];
SprintfLiteral(
msgbuf,
"[barrier verifier] Unmarked edge: %s %p '%s' edge to %s %p",
JS::GCTraceKindToAscii(node->thing.kind()),
node->thing.asCell(), edge.label,
JS::GCTraceKindToAscii(edge.thing.kind()), edge.thing.asCell());
MOZ_ReportAssertionFailure(msgbuf, __FILE__, __LINE__);
MOZ_CRASH();
}
}
}
node = NextNode(node);
}
}
marker.reset();
marker.stop();
js_delete(trc);
}
/*** Barrier Verifier Scheduling ***/
void gc::GCRuntime::verifyPreBarriers() {
if (verifyPreData) {
endVerifyPreBarriers();
} else {
startVerifyPreBarriers();
}
}
void gc::VerifyBarriers(JSRuntime* rt, VerifierType type) {
if (type == PreBarrierVerifier) {
rt->gc.verifyPreBarriers();
}
}
void gc::GCRuntime::maybeVerifyPreBarriers(bool always) {
if (!hasZealMode(ZealMode::VerifierPre)) {
return;
}
if (rt->mainContextFromOwnThread()->suppressGC) {
return;
}
if (verifyPreData) {
if (++verifyPreData->count < zealFrequency && !always) {
return;
}
endVerifyPreBarriers();
}
startVerifyPreBarriers();
}
void js::gc::MaybeVerifyBarriers(JSContext* cx, bool always) {
GCRuntime* gc = &cx->runtime()->gc;
gc->maybeVerifyPreBarriers(always);
}
void js::gc::GCRuntime::finishVerifier() {
if (verifyPreData) {
js_delete(verifyPreData.ref());
verifyPreData = nullptr;
}
}
struct GCChunkHasher {
typedef gc::TenuredChunk* Lookup;
/*
* Strip zeros for better distribution after multiplying by the golden
* ratio.
*/
static HashNumber hash(gc::TenuredChunk* chunk) {
MOZ_ASSERT(!(uintptr_t(chunk) & gc::ChunkMask));
return HashNumber(uintptr_t(chunk) >> gc::ChunkShift);
}
static bool match(gc::TenuredChunk* k, gc::TenuredChunk* l) {
MOZ_ASSERT(!(uintptr_t(k) & gc::ChunkMask));
MOZ_ASSERT(!(uintptr_t(l) & gc::ChunkMask));
return k == l;
}
};
class js::gc::MarkingValidator {
public:
explicit MarkingValidator(GCRuntime* gc);
void nonIncrementalMark(AutoGCSession& session);
void validate();
private:
GCRuntime* gc;
bool initialized;
using BitmapMap = HashMap<TenuredChunk*, UniquePtr<MarkBitmap>, GCChunkHasher,
SystemAllocPolicy>;
BitmapMap map;
};
js::gc::MarkingValidator::MarkingValidator(GCRuntime* gc)
: gc(gc), initialized(false) {}
void js::gc::MarkingValidator::nonIncrementalMark(AutoGCSession& session) {
/*
* Perform a non-incremental mark for all collecting zones and record
* the results for later comparison.
*
* Currently this does not validate gray marking.
*/
JSRuntime* runtime = gc->rt;
GCMarker* gcmarker = &gc->marker;
MOZ_ASSERT(!gcmarker->isWeakMarking());
/* Wait for off-thread parsing which can allocate. */
WaitForAllHelperThreads();
gc->waitBackgroundAllocEnd();
gc->waitBackgroundSweepEnd();
/* Save existing mark bits. */
{
AutoLockGC lock(gc);
for (auto chunk = gc->allNonEmptyChunks(lock); !chunk.done();
chunk.next()) {
MarkBitmap* bitmap = &chunk->markBits;
auto entry = MakeUnique<MarkBitmap>();
if (!entry) {
return;
}
memcpy((void*)entry->bitmap, (void*)bitmap->bitmap,
sizeof(bitmap->bitmap));
if (!map.putNew(chunk, std::move(entry))) {
return;
}
}
}
/*
* Temporarily clear the weakmaps' mark flags for the compartments we are
* collecting.
*/
WeakMapColors markedWeakMaps;
/*
* For saving, smush all of the keys into one big table and split them back
* up into per-zone tables when restoring.
*/
gc::WeakKeyTable savedWeakKeys(SystemAllocPolicy(),
runtime->randomHashCodeScrambler());
if (!savedWeakKeys.init()) {
return;
}
for (GCZonesIter zone(gc); !zone.done(); zone.next()) {
if (!WeakMapBase::saveZoneMarkedWeakMaps(zone, markedWeakMaps)) {
return;
}
AutoEnterOOMUnsafeRegion oomUnsafe;
for (gc::WeakKeyTable::Range r = zone->gcWeakKeys().all(); !r.empty();
r.popFront()) {
MOZ_ASSERT(r.front().key->asTenured().zone() == zone);
if (!savedWeakKeys.put(r.front().key, std::move(r.front().value))) {
oomUnsafe.crash("saving weak keys table for validator");
}
}
if (!zone->gcWeakKeys().clear()) {
oomUnsafe.crash("clearing weak keys table for validator");
}
}
/*
* After this point, the function should run to completion, so we shouldn't
* do anything fallible.
*/
initialized = true;
/* Re-do all the marking, but non-incrementally. */
js::gc::State state = gc->incrementalState;
gc->incrementalState = State::MarkRoots;
{
gcstats::AutoPhase ap(gc->stats(), gcstats::PhaseKind::PREPARE);
{
gcstats::AutoPhase ap(gc->stats(), gcstats::PhaseKind::UNMARK);
for (GCZonesIter zone(gc); !zone.done(); zone.next()) {
WeakMapBase::unmarkZone(zone);
}
MOZ_ASSERT(gcmarker->isDrained());
gcmarker->reset();
AutoLockGC lock(gc);
for (auto chunk = gc->allNonEmptyChunks(lock); !chunk.done();
chunk.next()) {
chunk->markBits.clear();
}
}
}
{
gcstats::AutoPhase ap(gc->stats(), gcstats::PhaseKind::MARK);
gc->traceRuntimeForMajorGC(gcmarker, session);
gc->incrementalState = State::Mark;
gc->drainMarkStack();
}
gc->incrementalState = State::Sweep;
{
gcstats::AutoPhase ap1(gc->stats(), gcstats::PhaseKind::SWEEP);
gcstats::AutoPhase ap2(gc->stats(), gcstats::PhaseKind::SWEEP_MARK);
gc->markAllWeakReferences();
/* Update zone state for gray marking. */
for (GCZonesIter zone(gc); !zone.done(); zone.next()) {
zone->changeGCState(Zone::MarkBlackOnly, Zone::MarkBlackAndGray);
}
AutoSetMarkColor setColorGray(*gcmarker, MarkColor::Gray);
gcmarker->setMainStackColor(MarkColor::Gray);
gc->markAllGrayReferences(gcstats::PhaseKind::SWEEP_MARK_GRAY);
gc->markAllWeakReferences();
gc->marker.setMainStackColor(MarkColor::Black);
/* Restore zone state. */
for (GCZonesIter zone(gc); !zone.done(); zone.next()) {
zone->changeGCState(Zone::MarkBlackAndGray, Zone::MarkBlackOnly);
}
MOZ_ASSERT(gc->marker.isDrained());
}
/* Take a copy of the non-incremental mark state and restore the original. */
{
AutoLockGC lock(gc);
for (auto chunk = gc->allNonEmptyChunks(lock); !chunk.done();
chunk.next()) {
MarkBitmap* bitmap = &chunk->markBits;
auto ptr = map.lookup(chunk);
MOZ_RELEASE_ASSERT(ptr, "Chunk not found in map");
MarkBitmap* entry = ptr->value().get();
for (size_t i = 0; i < MarkBitmap::WordCount; i++) {
uintptr_t v = entry->bitmap[i];
entry->bitmap[i] = uintptr_t(bitmap->bitmap[i]);
bitmap->bitmap[i] = v;
}
}
}
for (GCZonesIter zone(gc); !zone.done(); zone.next()) {
WeakMapBase::unmarkZone(zone);
AutoEnterOOMUnsafeRegion oomUnsafe;
if (!zone->gcWeakKeys().clear()) {
oomUnsafe.crash("clearing weak keys table for validator");
}
}
WeakMapBase::restoreMarkedWeakMaps(markedWeakMaps);
for (gc::WeakKeyTable::Range r = savedWeakKeys.all(); !r.empty();
r.popFront()) {
AutoEnterOOMUnsafeRegion oomUnsafe;
Zone* zone = r.front().key->asTenured().zone();
if (!zone->gcWeakKeys().put(r.front().key, std::move(r.front().value))) {
oomUnsafe.crash("restoring weak keys table for validator");
}
}
gc->incrementalState = state;
}
void js::gc::MarkingValidator::validate() {
/*
* Validates the incremental marking for a single compartment by comparing
* the mark bits to those previously recorded for a non-incremental mark.
*/
if (!initialized) {
return;
}
MOZ_ASSERT(!gc->marker.isWeakMarking());
gc->waitBackgroundSweepEnd();
AutoLockGC lock(gc->rt);
for (auto chunk = gc->allNonEmptyChunks(lock); !chunk.done(); chunk.next()) {
BitmapMap::Ptr ptr = map.lookup(chunk);
if (!ptr) {
continue; /* Allocated after we did the non-incremental mark. */
}
MarkBitmap* bitmap = ptr->value().get();
MarkBitmap* incBitmap = &chunk->markBits;
for (size_t i = 0; i < ArenasPerChunk; i++) {
if (chunk->decommittedArenas[i]) {
continue;
}
Arena* arena = &chunk->arenas[i];
if (!arena->allocated()) {
continue;
}
if (!arena->zone->isGCSweeping()) {
continue;
}
AllocKind kind = arena->getAllocKind();
uintptr_t thing = arena->thingsStart();
uintptr_t end = arena->thingsEnd();
while (thing < end) {
auto* cell = reinterpret_cast<TenuredCell*>(thing);
/*
* If a non-incremental GC wouldn't have collected a cell, then
* an incremental GC won't collect it.
*/
if (bitmap->isMarkedAny(cell)) {
MOZ_RELEASE_ASSERT(incBitmap->isMarkedAny(cell));
}
/*
* If the cycle collector isn't allowed to collect an object
* after a non-incremental GC has run, then it isn't allowed to
* collected it after an incremental GC.
*/
if (!bitmap->isMarkedGray(cell)) {
MOZ_RELEASE_ASSERT(!incBitmap->isMarkedGray(cell));
}
thing += Arena::thingSize(kind);
}
}
}
}
void GCRuntime::computeNonIncrementalMarkingForValidation(
AutoGCSession& session) {
MOZ_ASSERT(!markingValidator);
if (isIncremental && hasZealMode(ZealMode::IncrementalMarkingValidator)) {
markingValidator = js_new<MarkingValidator>(this);
}
if (markingValidator) {
markingValidator->nonIncrementalMark(session);
}
}
void GCRuntime::validateIncrementalMarking() {
if (markingValidator) {
markingValidator->validate();
}
}
void GCRuntime::finishMarkingValidation() {
js_delete(markingValidator.ref());
markingValidator = nullptr;
}
#endif /* JS_GC_ZEAL */
#if defined(JS_GC_ZEAL) || defined(DEBUG)
class HeapCheckTracerBase : public JS::CallbackTracer {
public:
explicit HeapCheckTracerBase(JSRuntime* rt, JS::TraceOptions options);
bool traceHeap(AutoTraceSession& session);
virtual void checkCell(Cell* cell) = 0;
protected:
void dumpCellInfo(Cell* cell);
void dumpCellPath();
Cell* parentCell() {
return parentIndex == -1 ? nullptr : stack[parentIndex].thing.asCell();
}
size_t failures;
private:
void onChild(const JS::GCCellPtr& thing) override;
struct WorkItem {
WorkItem(JS::GCCellPtr thing, const char* name, int parentIndex)
: thing(thing),
name(name),
parentIndex(parentIndex),
processed(false) {}
JS::GCCellPtr thing;
const char* name;
int parentIndex;
bool processed;
};
JSRuntime* rt;
bool oom;
HashSet<Cell*, DefaultHasher<Cell*>, SystemAllocPolicy> visited;
Vector<WorkItem, 0, SystemAllocPolicy> stack;
int parentIndex;
};
HeapCheckTracerBase::HeapCheckTracerBase(JSRuntime* rt,
JS::TraceOptions options)
: CallbackTracer(rt, JS::TracerKind::Callback, options),
failures(0),
rt(rt),
oom(false),
parentIndex(-1) {}
void HeapCheckTracerBase::onChild(const JS::GCCellPtr& thing) {
Cell* cell = thing.asCell();
checkCell(cell);
if (visited.lookup(cell)) {
return;
}
if (!visited.put(cell)) {
oom = true;
return;
}
// Don't trace into GC things owned by another runtime.
if (cell->runtimeFromAnyThread() != rt) {
return;
}
// Don't trace into GC in zones being used by helper threads.
Zone* zone = thing.asCell()->zone();
if (zone->usedByHelperThread()) {
return;
}
WorkItem item(thing, context().name(), parentIndex);
if (!stack.append(item)) {
oom = true;
}
}
bool HeapCheckTracerBase::traceHeap(AutoTraceSession& session) {
// The analysis thinks that traceRuntime might GC by calling a GC callback.
JS::AutoSuppressGCAnalysis nogc;
if (!rt->isBeingDestroyed()) {
rt->gc.traceRuntime(this, session);
}
while (!stack.empty() && !oom) {
WorkItem item = stack.back();
if (item.processed) {
stack.popBack();
} else {
parentIndex = stack.length() - 1;
stack.back().processed = true;
TraceChildren(this, item.thing);
}
}
return !oom;
}
void HeapCheckTracerBase::dumpCellInfo(Cell* cell) {
auto kind = cell->getTraceKind();
JSObject* obj =
kind == JS::TraceKind::Object ? static_cast<JSObject*>(cell) : nullptr;
fprintf(stderr, "%s %s", cell->color().name(), GCTraceKindToAscii(kind));
if (obj) {
fprintf(stderr, " %s", obj->getClass()->name);
}
fprintf(stderr, " %p", cell);
if (obj) {
fprintf(stderr, " (compartment %p)", obj->compartment());
}
}
void HeapCheckTracerBase::dumpCellPath() {
const char* name = context().name();
for (int index = parentIndex; index != -1; index = stack[index].parentIndex) {
const WorkItem& parent = stack[index];
Cell* cell = parent.thing.asCell();
fprintf(stderr, " from ");
dumpCellInfo(cell);
fprintf(stderr, " %s edge\n", name);
name = parent.name;
}
fprintf(stderr, " from root %s\n", name);
}
class CheckHeapTracer final : public HeapCheckTracerBase {
public:
enum GCType { Moving, NonMoving };
explicit CheckHeapTracer(JSRuntime* rt, GCType type);
void check(AutoTraceSession& session);
private:
void checkCell(Cell* cell) override;
GCType gcType;
};
CheckHeapTracer::CheckHeapTracer(JSRuntime* rt, GCType type)
: HeapCheckTracerBase(rt, JS::WeakMapTraceAction::TraceKeysAndValues),
gcType(type) {}
inline static bool IsValidGCThingPointer(Cell* cell) {
return (uintptr_t(cell) & CellAlignMask) == 0;
}
void CheckHeapTracer::checkCell(Cell* cell) {
// Moving
if (!IsValidGCThingPointer(cell) ||
((gcType == GCType::Moving) && !IsGCThingValidAfterMovingGC(cell)) ||
((gcType == GCType::NonMoving) && cell->isForwarded())) {
failures++;
fprintf(stderr, "Bad pointer %p\n", cell);
dumpCellPath();
}
}
void CheckHeapTracer::check(AutoTraceSession& session) {
if (!traceHeap(session)) {
return;
}
if (failures) {
fprintf(stderr, "Heap check: %zu failure(s)\n", failures);
}
MOZ_RELEASE_ASSERT(failures == 0);
}
void js::gc::CheckHeapAfterGC(JSRuntime* rt) {
AutoTraceSession session(rt);
CheckHeapTracer::GCType gcType;
if (rt->gc.nursery().isEmpty()) {
gcType = CheckHeapTracer::GCType::Moving;
} else {
gcType = CheckHeapTracer::GCType::NonMoving;
}
CheckHeapTracer tracer(rt, gcType);
tracer.check(session);
}
class CheckGrayMarkingTracer final : public HeapCheckTracerBase {
public:
explicit CheckGrayMarkingTracer(JSRuntime* rt);
bool check(AutoTraceSession& session);
private:
void checkCell(Cell* cell) override;
};
CheckGrayMarkingTracer::CheckGrayMarkingTracer(JSRuntime* rt)
: HeapCheckTracerBase(rt, JS::TraceOptions(JS::WeakMapTraceAction::Skip,
JS::WeakEdgeTraceAction::Skip)) {
// Weak gray->black edges are allowed.
}
void CheckGrayMarkingTracer::checkCell(Cell* cell) {
Cell* parent = parentCell();
if (!parent) {
return;
}
if (parent->isMarkedBlack() && cell->isMarkedGray()) {
failures++;
fprintf(stderr, "Found black to gray edge to ");
dumpCellInfo(cell);
fprintf(stderr, "\n");
dumpCellPath();
# ifdef DEBUG
if (parent->is<JSObject>()) {
fprintf(stderr, "\nSource: ");
DumpObject(parent->as<JSObject>(), stderr);
}
if (cell->is<JSObject>()) {
fprintf(stderr, "\nTarget: ");
DumpObject(cell->as<JSObject>(), stderr);
}
# endif
}
}
bool CheckGrayMarkingTracer::check(AutoTraceSession& session) {
if (!traceHeap(session)) {
return true; // Ignore failure.
}
return failures == 0;
}
JS_FRIEND_API bool js::CheckGrayMarkingState(JSRuntime* rt) {
MOZ_ASSERT(!JS::RuntimeHeapIsCollecting());
MOZ_ASSERT(!rt->gc.isIncrementalGCInProgress());
if (!rt->gc.areGrayBitsValid()) {
return true;
}
gcstats::AutoPhase ap(rt->gc.stats(), gcstats::PhaseKind::TRACE_HEAP);
AutoTraceSession session(rt);
CheckGrayMarkingTracer tracer(rt);
return tracer.check(session);
}
static JSObject* MaybeGetDelegate(Cell* cell) {
if (!cell->is<JSObject>()) {
return nullptr;
}
JSObject* object = cell->as<JSObject>();
return js::UncheckedUnwrapWithoutExpose(object);
}
bool js::gc::CheckWeakMapEntryMarking(const WeakMapBase* map, Cell* key,
Cell* value) {
bool ok = true;
Zone* zone = map->zone();
MOZ_ASSERT(CurrentThreadCanAccessZone(zone));
MOZ_ASSERT(zone->isGCMarking());
JSObject* object = map->memberOf;
MOZ_ASSERT_IF(object, object->zone() == zone);
// Debugger weak maps can have keys in different zones.
Zone* keyZone = key->zoneFromAnyThread();
MOZ_ASSERT_IF(!map->allowKeysInOtherZones(),
keyZone == zone || keyZone->isAtomsZone());
Zone* valueZone = value->zoneFromAnyThread();
MOZ_ASSERT(valueZone == zone || valueZone->isAtomsZone());
if (object && object->color() != map->mapColor) {
fprintf(stderr, "WeakMap object is marked differently to the map\n");
fprintf(stderr, "(map %p is %s, object %p is %s)\n", map,
map->mapColor.name(), object, object->color().name());
ok = false;
}
// Values belonging to other runtimes or in uncollected zones are treated as
// black.
JSRuntime* mapRuntime = zone->runtimeFromAnyThread();
auto effectiveColor = [=](Cell* cell, Zone* cellZone) -> CellColor {
if (cell->runtimeFromAnyThread() != mapRuntime) {
return CellColor::Black;
}
if (cellZone->isGCMarkingOrSweeping()) {
return cell->color();
}
return CellColor::Black;
};
CellColor valueColor = effectiveColor(value, valueZone);
CellColor keyColor = effectiveColor(key, keyZone);
if (valueColor < std::min(map->mapColor, keyColor)) {
fprintf(stderr, "WeakMap value is less marked than map and key\n");
fprintf(stderr, "(map %p is %s, key %p is %s, value %p is %s)\n", map,
map->mapColor.name(), key, keyColor.name(), value,
valueColor.name());
# ifdef DEBUG
fprintf(stderr, "Key:\n");
key->dump();
if (auto delegate = MaybeGetDelegate(key); delegate) {
fprintf(stderr, "Delegate:\n");
delegate->dump();
}
fprintf(stderr, "Value:\n");
value->dump();
# endif
ok = false;
}
JSObject* delegate = MaybeGetDelegate(key);
if (!delegate) {
return ok;
}
CellColor delegateColor = effectiveColor(delegate, delegate->zone());
if (keyColor < std::min(map->mapColor, delegateColor)) {
fprintf(stderr, "WeakMap key is less marked than map or delegate\n");
fprintf(stderr, "(map %p is %s, delegate %p is %s, key %p is %s)\n", map,
map->mapColor.name(), delegate, delegateColor.name(), key,
keyColor.name());
ok = false;
}
return ok;
}
#endif // defined(JS_GC_ZEAL) || defined(DEBUG)
#ifdef DEBUG
// Return whether an arbitrary pointer is within a cell with the given
// traceKind. Only for assertions.
bool GCRuntime::isPointerWithinTenuredCell(void* ptr, JS::TraceKind traceKind) {
AutoLockGC lock(this);
for (auto chunk = allNonEmptyChunks(lock); !chunk.done(); chunk.next()) {
MOZ_ASSERT(!chunk->isNurseryChunk());
if (ptr >= &chunk->arenas[0] && ptr < &chunk->arenas[ArenasPerChunk]) {
auto* arena = reinterpret_cast<Arena*>(uintptr_t(ptr) & ~ArenaMask);
if (!arena->allocated()) {
return false;
}
return MapAllocToTraceKind(arena->getAllocKind()) == traceKind;
}
}
return false;
}
#endif // DEBUG
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