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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 "vm/PropMap-inl.h"
#include "gc/Allocator.h"
#include "gc/HashUtil.h"
#include "js/GCVector.h"
#include "vm/JSObject.h"
#include "gc/GCContext-inl.h"
#include "gc/Marking-inl.h"
#include "vm/ObjectFlags-inl.h"
using namespace js;
void PropMap::addSizeOfExcludingThis(mozilla::MallocSizeOf mallocSizeOf,
size_t* children, size_t* tables) const {
if (isShared() && asShared()->hasChildrenSet()) {
auto* set = asShared()->treeDataRef().children.toChildrenSet();
*children += set->shallowSizeOfIncludingThis(mallocSizeOf);
}
if (canHaveTable() && asLinked()->hasTable()) {
*tables += asLinked()->data_.table->sizeOfIncludingThis(mallocSizeOf);
}
}
// static
SharedPropMap* SharedPropMap::create(JSContext* cx, Handle<SharedPropMap*> prev,
HandleId id, PropertyInfo prop) {
// If the first property has a slot number <= MaxSlotNumber, all properties
// added later will have a slot number <= CompactPropertyInfo::MaxSlotNumber
// so we can use a CompactPropMap.
static constexpr size_t MaxFirstSlot =
CompactPropertyInfo::MaxSlotNumber - (PropMap::Capacity - 1);
if (!prev && prop.maybeSlot() <= MaxFirstSlot) {
return cx->newCell<CompactPropMap>(id, prop);
}
return cx->newCell<NormalPropMap>(prev, id, prop);
}
// static
SharedPropMap* SharedPropMap::createInitial(JSContext* cx, HandleId id,
PropertyInfo prop) {
// Lookup or create a shared map based on the first property.
using Lookup = InitialPropMapHasher::Lookup;
auto& table = cx->zone()->shapeZone().initialPropMaps;
auto p = MakeDependentAddPtr(cx, table, Lookup(id, prop));
if (p) {
return *p;
}
SharedPropMap* result = create(cx, /* prev = */ nullptr, id, prop);
if (!result) {
return nullptr;
}
Lookup lookup(id, prop);
if (!p.add(cx, table, lookup, result)) {
return nullptr;
}
return result;
}
// static
SharedPropMap* SharedPropMap::clone(JSContext* cx, Handle<SharedPropMap*> map,
uint32_t length) {
MOZ_ASSERT(length > 0);
if (map->isCompact()) {
Rooted<CompactPropMap*> prev(cx, map->asCompact());
return cx->newCell<CompactPropMap>(prev, length);
}
Rooted<NormalPropMap*> prev(cx, map->asNormal());
return cx->newCell<NormalPropMap>(prev, length);
}
// static
DictionaryPropMap* SharedPropMap::toDictionaryMap(JSContext* cx,
Handle<SharedPropMap*> map,
uint32_t length) {
// Starting at the last map, clone each shared map to a new dictionary map.
Rooted<DictionaryPropMap*> lastDictMap(cx);
Rooted<DictionaryPropMap*> nextDictMap(cx);
Rooted<SharedPropMap*> sharedMap(cx, map);
uint32_t sharedLength = length;
while (true) {
sharedMap->setHadDictionaryConversion();
DictionaryPropMap* dictMap;
if (sharedMap->isCompact()) {
Rooted<CompactPropMap*> prev(cx, sharedMap->asCompact());
dictMap = cx->newCell<DictionaryPropMap>(prev, sharedLength);
} else {
Rooted<NormalPropMap*> prev(cx, sharedMap->asNormal());
dictMap = cx->newCell<DictionaryPropMap>(prev, sharedLength);
}
if (!dictMap) {
return nullptr;
}
if (!lastDictMap) {
lastDictMap = dictMap;
}
if (nextDictMap) {
nextDictMap->initPrevious(dictMap);
}
nextDictMap = dictMap;
if (!sharedMap->hasPrevious()) {
break;
}
sharedMap = sharedMap->asNormal()->previous();
sharedLength = PropMap::Capacity;
}
return lastDictMap;
}
static MOZ_ALWAYS_INLINE SharedPropMap* PropMapChildReadBarrier(
SharedPropMap* parent, SharedPropMap* child) {
JS::Zone* zone = child->zone();
if (zone->needsIncrementalBarrier()) {
// We need a read barrier for the map tree, since these are weak
// pointers.
ReadBarrier(child);
return child;
}
if (MOZ_UNLIKELY(zone->isGCSweeping() &&
IsAboutToBeFinalizedUnbarriered(child))) {
// The map we've found is unreachable and due to be finalized, so
// remove our weak reference to it and don't use it.
MOZ_ASSERT(parent->isMarkedAny());
parent->removeChild(zone->runtimeFromMainThread()->gcContext(), child);
return nullptr;
}
// We don't yield to the mutator when the zone is in this state so we don't
// need to account for it here.
MOZ_ASSERT(!zone->isGCCompacting());
return child;
}
SharedPropMap* SharedPropMap::lookupChild(uint32_t length, HandleId id,
PropertyInfo prop) {
MOZ_ASSERT(length > 0);
SharedChildrenPtr children = treeDataRef().children;
if (children.isNone()) {
return nullptr;
}
if (!hasChildrenSet()) {
SharedPropMapAndIndex prevChild = children.toSingleChild();
if (prevChild.index() == length - 1) {
SharedPropMap* child = prevChild.map();
uint32_t newPropIndex = indexOfNextProperty(length - 1);
if (child->matchProperty(newPropIndex, id, prop)) {
return PropMapChildReadBarrier(this, child);
}
}
return nullptr;
}
SharedChildrenSet* set = children.toChildrenSet();
SharedChildrenHasher::Lookup lookup(id, prop, length - 1);
if (auto p = set->lookup(lookup)) {
MOZ_ASSERT(p->index() == length - 1);
SharedPropMap* child = p->map();
return PropMapChildReadBarrier(this, child);
}
return nullptr;
}
bool SharedPropMap::addChild(JSContext* cx, SharedPropMapAndIndex child,
HandleId id, PropertyInfo prop) {
SharedPropMap* childMap = child.map();
#ifdef DEBUG
// If the parent map was full, the child map must have the parent as
// |previous| map. Else, the parent and child have the same |previous| map.
if (childMap->hasPrevious()) {
if (child.index() == PropMap::Capacity - 1) {
MOZ_ASSERT(childMap->asLinked()->previous() == this);
} else {
MOZ_ASSERT(childMap->asLinked()->previous() == asLinked()->previous());
}
} else {
MOZ_ASSERT(!hasPrevious());
}
#endif
SharedChildrenPtr& childrenRef = treeDataRef().children;
if (childrenRef.isNone()) {
childrenRef.setSingleChild(child);
childMap->treeDataRef().setParent(this, child.index());
return true;
}
SharedChildrenHasher::Lookup lookup(id, prop, child.index());
if (hasChildrenSet()) {
if (!childrenRef.toChildrenSet()->putNew(lookup, child)) {
ReportOutOfMemory(cx);
return false;
}
} else {
auto hash = MakeUnique<SharedChildrenSet>();
if (!hash || !hash->reserve(2)) {
ReportOutOfMemory(cx);
return false;
}
SharedPropMapAndIndex firstChild = childrenRef.toSingleChild();
SharedPropMap* firstChildMap = firstChild.map();
uint32_t firstChildIndex = indexOfNextProperty(firstChild.index());
SharedChildrenHasher::Lookup lookupFirst(
firstChildMap->getPropertyInfoWithKey(firstChildIndex),
firstChild.index());
hash->putNewInfallible(lookupFirst, firstChild);
hash->putNewInfallible(lookup, child);
childrenRef.setChildrenSet(hash.release());
setHasChildrenSet();
AddCellMemory(this, sizeof(SharedChildrenSet), MemoryUse::PropMapChildren);
}
childMap->treeDataRef().setParent(this, child.index());
return true;
}
// static
bool SharedPropMap::addProperty(JSContext* cx, const JSClass* clasp,
MutableHandle<SharedPropMap*> map,
uint32_t* mapLength, HandleId id,
PropertyFlags flags, ObjectFlags* objectFlags,
uint32_t* slot) {
MOZ_ASSERT(!flags.isCustomDataProperty());
*slot = SharedPropMap::slotSpan(clasp, map, *mapLength);
if (MOZ_UNLIKELY(*slot > SHAPE_MAXIMUM_SLOT)) {
ReportAllocationOverflow(cx);
return false;
}
*objectFlags =
GetObjectFlagsForNewProperty(clasp, *objectFlags, id, flags, cx);
PropertyInfo prop = PropertyInfo(flags, *slot);
return addPropertyInternal(cx, map, mapLength, id, prop);
}
// static
bool SharedPropMap::addPropertyInReservedSlot(
JSContext* cx, const JSClass* clasp, MutableHandle<SharedPropMap*> map,
uint32_t* mapLength, HandleId id, PropertyFlags flags, uint32_t slot,
ObjectFlags* objectFlags) {
MOZ_ASSERT(!flags.isCustomDataProperty());
MOZ_ASSERT(slot < JSCLASS_RESERVED_SLOTS(clasp));
MOZ_ASSERT_IF(map, map->lastUsedSlot(*mapLength) < slot);
*objectFlags =
GetObjectFlagsForNewProperty(clasp, *objectFlags, id, flags, cx);
PropertyInfo prop = PropertyInfo(flags, slot);
return addPropertyInternal(cx, map, mapLength, id, prop);
}
// static
bool SharedPropMap::addPropertyWithKnownSlot(JSContext* cx,
const JSClass* clasp,
MutableHandle<SharedPropMap*> map,
uint32_t* mapLength, HandleId id,
PropertyFlags flags, uint32_t slot,
ObjectFlags* objectFlags) {
MOZ_ASSERT(!flags.isCustomDataProperty());
if (MOZ_UNLIKELY(slot < JSCLASS_RESERVED_SLOTS(clasp))) {
return addPropertyInReservedSlot(cx, clasp, map, mapLength, id, flags, slot,
objectFlags);
}
MOZ_ASSERT(slot == SharedPropMap::slotSpan(clasp, map, *mapLength));
MOZ_RELEASE_ASSERT(slot <= SHAPE_MAXIMUM_SLOT);
*objectFlags =
GetObjectFlagsForNewProperty(clasp, *objectFlags, id, flags, cx);
PropertyInfo prop = PropertyInfo(flags, slot);
return addPropertyInternal(cx, map, mapLength, id, prop);
}
// static
bool SharedPropMap::addCustomDataProperty(JSContext* cx, const JSClass* clasp,
MutableHandle<SharedPropMap*> map,
uint32_t* mapLength, HandleId id,
PropertyFlags flags,
ObjectFlags* objectFlags) {
MOZ_ASSERT(flags.isCustomDataProperty());
// Custom data properties don't have a slot. Copy the last property's slot
// number to simplify the implementation of SharedPropMap::slotSpan.
uint32_t slot = map ? map->lastUsedSlot(*mapLength) : SHAPE_INVALID_SLOT;
*objectFlags =
GetObjectFlagsForNewProperty(clasp, *objectFlags, id, flags, cx);
PropertyInfo prop = PropertyInfo(flags, slot);
return addPropertyInternal(cx, map, mapLength, id, prop);
}
// static
bool SharedPropMap::addPropertyInternal(JSContext* cx,
MutableHandle<SharedPropMap*> map,
uint32_t* mapLength, HandleId id,
PropertyInfo prop) {
if (!map) {
// Adding the first property.
MOZ_ASSERT(*mapLength == 0);
map.set(SharedPropMap::createInitial(cx, id, prop));
if (!map) {
return false;
}
*mapLength = 1;
return true;
}
MOZ_ASSERT(*mapLength > 0);
if (*mapLength < PropMap::Capacity) {
// Use the next map entry if possible.
if (!map->hasKey(*mapLength)) {
if (map->canHaveTable()) {
JS::AutoCheckCannotGC nogc;
if (PropMapTable* table = map->asLinked()->maybeTable(nogc)) {
if (!table->add(cx, id, PropMapAndIndex(map, *mapLength))) {
return false;
}
}
}
map->initProperty(*mapLength, id, prop);
*mapLength += 1;
return true;
}
if (map->matchProperty(*mapLength, id, prop)) {
*mapLength += 1;
return true;
}
// The next entry can't be used so look up or create a child map. The child
// map is a clone of this map up to mapLength, with the new property stored
// as the next entry.
if (SharedPropMap* child = map->lookupChild(*mapLength, id, prop)) {
map.set(child);
*mapLength += 1;
return true;
}
SharedPropMap* child = SharedPropMap::clone(cx, map, *mapLength);
if (!child) {
return false;
}
child->initProperty(*mapLength, id, prop);
SharedPropMapAndIndex childEntry(child, *mapLength - 1);
if (!map->addChild(cx, childEntry, id, prop)) {
return false;
}
map.set(child);
*mapLength += 1;
return true;
}
// This map is full so look up or create a child map.
MOZ_ASSERT(*mapLength == PropMap::Capacity);
if (SharedPropMap* child = map->lookupChild(*mapLength, id, prop)) {
map.set(child);
*mapLength = 1;
return true;
}
SharedPropMap* child = SharedPropMap::create(cx, map, id, prop);
if (!child) {
return false;
}
SharedPropMapAndIndex childEntry(child, PropMap::Capacity - 1);
if (!map->addChild(cx, childEntry, id, prop)) {
return false;
}
// As an optimization, pass the table to the new child map, unless adding the
// property to it OOMs. Measurements indicate this gets rid of a large number
// of PropMapTable allocations because we don't need to create a second table
// when the parent map won't be used again as last map.
if (map->canHaveTable()) {
JS::AutoCheckCannotGC nogc;
if (PropMapTable* table = map->asLinked()->maybeTable(nogc)) {
// Trigger a pre-barrier on the parent map to appease the pre-barrier
// verifier, because edges from the table are disappearing (even though
// these edges are strictly redundant with the |previous| maps).
gc::PreWriteBarrier(map.get());
if (table->add(cx, id, PropMapAndIndex(child, 0))) {
map->asLinked()->handOffTableTo(child->asLinked());
} else {
cx->recoverFromOutOfMemory();
}
}
}
map.set(child);
*mapLength = 1;
return true;
}
static PropertyFlags ComputeFlagsForSealOrFreeze(PropertyKey key,
PropertyFlags flags,
IntegrityLevel level) {
// Private fields are not visible to SetIntegrityLevel.
if (key.isSymbol() && key.toSymbol()->isPrivateName()) {
return flags;
}
// Make all properties non-configurable; if freezing, make data properties
// read-only.
flags.clearFlag(PropertyFlag::Configurable);
if (level == IntegrityLevel::Frozen && flags.isDataDescriptor()) {
flags.clearFlag(PropertyFlag::Writable);
}
return flags;
}
// static
bool SharedPropMap::freezeOrSealProperties(JSContext* cx, IntegrityLevel level,
const JSClass* clasp,
MutableHandle<SharedPropMap*> map,
uint32_t mapLength,
ObjectFlags* objectFlags) {
// Add all maps to a Vector so we can iterate over them in reverse order
// (property definition order).
JS::RootedVector<SharedPropMap*> maps(cx);
{
SharedPropMap* curMap = map;
while (true) {
if (!maps.append(curMap)) {
return false;
}
if (!curMap->hasPrevious()) {
break;
}
curMap = curMap->asNormal()->previous();
}
}
// Build a new SharedPropMap by adding each property with the changed
// attributes.
Rooted<SharedPropMap*> newMap(cx);
uint32_t newMapLength = 0;
Rooted<PropertyKey> key(cx);
Rooted<SharedPropMap*> curMap(cx);
for (size_t i = maps.length(); i > 0; i--) {
curMap = maps[i - 1];
uint32_t len = (i == 1) ? mapLength : PropMap::Capacity;
for (uint32_t j = 0; j < len; j++) {
key = curMap->getKey(j);
PropertyInfo prop = curMap->getPropertyInfo(j);
PropertyFlags flags =
ComputeFlagsForSealOrFreeze(key, prop.flags(), level);
if (prop.isCustomDataProperty()) {
if (!addCustomDataProperty(cx, clasp, &newMap, &newMapLength, key,
flags, objectFlags)) {
return false;
}
} else {
if (!addPropertyWithKnownSlot(cx, clasp, &newMap, &newMapLength, key,
flags, prop.slot(), objectFlags)) {
return false;
}
}
}
}
map.set(newMap);
MOZ_ASSERT(newMapLength == mapLength);
return true;
}
void LinkedPropMap::handOffTableTo(LinkedPropMap* next) {
MOZ_ASSERT(hasTable());
MOZ_ASSERT(!next->hasTable());
next->data_.table = data_.table;
data_.table = nullptr;
// Note: for tables currently only sizeof(PropMapTable) is tracked.
RemoveCellMemory(this, sizeof(PropMapTable), MemoryUse::PropMapTable);
AddCellMemory(next, sizeof(PropMapTable), MemoryUse::PropMapTable);
}
void DictionaryPropMap::handOffLastMapStateTo(DictionaryPropMap* newLast) {
// A dictionary object's last map contains the table, slot freeList, and
// holeCount. These fields always have their initial values for non-last maps.
MOZ_ASSERT(this != newLast);
if (asLinked()->hasTable()) {
asLinked()->handOffTableTo(newLast->asLinked());
}
MOZ_ASSERT(newLast->freeList_ == SHAPE_INVALID_SLOT);
newLast->freeList_ = freeList_;
freeList_ = SHAPE_INVALID_SLOT;
MOZ_ASSERT(newLast->holeCount_ == 0);
newLast->holeCount_ = holeCount_;
holeCount_ = 0;
}
// static
bool DictionaryPropMap::addProperty(JSContext* cx, const JSClass* clasp,
MutableHandle<DictionaryPropMap*> map,
uint32_t* mapLength, HandleId id,
PropertyFlags flags, uint32_t slot,
ObjectFlags* objectFlags) {
MOZ_ASSERT(map);
*objectFlags =
GetObjectFlagsForNewProperty(clasp, *objectFlags, id, flags, cx);
PropertyInfo prop = PropertyInfo(flags, slot);
if (*mapLength < PropMap::Capacity) {
JS::AutoCheckCannotGC nogc;
if (PropMapTable* table = map->asLinked()->maybeTable(nogc)) {
if (!table->add(cx, id, PropMapAndIndex(map, *mapLength))) {
return false;
}
}
map->initProperty(*mapLength, id, prop);
*mapLength += 1;
return true;
}
DictionaryPropMap* newMap = cx->newCell<DictionaryPropMap>(map, id, prop);
if (!newMap) {
return false;
}
JS::AutoCheckCannotGC nogc;
if (PropMapTable* table = map->asLinked()->maybeTable(nogc)) {
if (!table->add(cx, id, PropMapAndIndex(newMap, 0))) {
return false;
}
}
MOZ_ASSERT(newMap->previous() == map);
map->handOffLastMapStateTo(newMap);
map.set(newMap);
*mapLength = 1;
return true;
}
void DictionaryPropMap::changeProperty(JSContext* cx, const JSClass* clasp,
uint32_t index, PropertyFlags flags,
uint32_t slot,
ObjectFlags* objectFlags) {
MOZ_ASSERT(hasKey(index));
*objectFlags = GetObjectFlagsForNewProperty(clasp, *objectFlags,
getKey(index), flags, cx);
linkedData_.propInfos[index] = PropertyInfo(flags, slot);
}
void DictionaryPropMap::freezeOrSealProperties(JSContext* cx,
IntegrityLevel level,
const JSClass* clasp,
uint32_t mapLength,
ObjectFlags* objectFlags) {
DictionaryPropMap* curMap = this;
do {
for (uint32_t i = 0; i < mapLength; i++) {
if (!curMap->hasKey(i)) {
continue;
}
PropertyKey key = curMap->getKey(i);
PropertyFlags flags = curMap->getPropertyInfo(i).flags();
flags = ComputeFlagsForSealOrFreeze(key, flags, level);
curMap->changePropertyFlags(cx, clasp, i, flags, objectFlags);
}
curMap = curMap->previous();
mapLength = PropMap::Capacity;
} while (curMap);
}
// static
void DictionaryPropMap::skipTrailingHoles(MutableHandle<DictionaryPropMap*> map,
uint32_t* mapLength) {
// After removing a property, rewind map/mapLength so that the last property
// is not a hole. This ensures accessing the last property of a map can always
// be done without checking for holes.
while (true) {
MOZ_ASSERT(*mapLength > 0);
do {
if (map->hasKey(*mapLength - 1)) {
return;
}
map->decHoleCount();
*mapLength -= 1;
} while (*mapLength > 0);
if (!map->previous()) {
// The dictionary map is empty, return the initial map with mapLength 0.
MOZ_ASSERT(*mapLength == 0);
MOZ_ASSERT(map->holeCount_ == 0);
return;
}
map->handOffLastMapStateTo(map->previous());
map.set(map->previous());
*mapLength = PropMap::Capacity;
}
}
// static
void DictionaryPropMap::removeProperty(JSContext* cx,
MutableHandle<DictionaryPropMap*> map,
uint32_t* mapLength, PropMapTable* table,
PropMapTable::Ptr& ptr) {
MOZ_ASSERT(map);
MOZ_ASSERT(*mapLength > 0);
JS::AutoCheckCannotGC nogc;
MOZ_ASSERT(map->asLinked()->maybeTable(nogc) == table);
bool removingLast = (map == ptr->map() && *mapLength - 1 == ptr->index());
ptr->map()->asDictionary()->clearProperty(ptr->index());
map->incHoleCount();
table->remove(ptr);
if (removingLast) {
skipTrailingHoles(map, mapLength);
}
maybeCompact(cx, map, mapLength);
}
// static
void DictionaryPropMap::densifyElements(JSContext* cx,
MutableHandle<DictionaryPropMap*> map,
uint32_t* mapLength,
NativeObject* obj) {
MOZ_ASSERT(map);
MOZ_ASSERT(*mapLength > 0);
JS::AutoCheckCannotGC nogc;
PropMapTable* table = map->asLinked()->maybeTable(nogc);
DictionaryPropMap* currentMap = map;
uint32_t currentLen = *mapLength;
do {
for (uint32_t i = 0; i < currentLen; i++) {
PropertyKey key = currentMap->getKey(i);
uint32_t index;
if (!IdIsIndex(key, &index)) {
continue;
}
// The caller must have checked all sparse elements are plain data
// properties.
PropertyInfo prop = currentMap->getPropertyInfo(i);
MOZ_ASSERT(prop.flags() == PropertyFlags::defaultDataPropFlags);
uint32_t slot = prop.slot();
Value value = obj->getSlot(slot);
obj->setDenseElement(index, value);
obj->freeDictionarySlot(slot);
if (table) {
PropMapTable::Ptr p = table->lookupRaw(key);
MOZ_ASSERT(p);
table->remove(p);
}
currentMap->clearProperty(i);
map->incHoleCount();
}
currentMap = currentMap->previous();
currentLen = PropMap::Capacity;
} while (currentMap);
skipTrailingHoles(map, mapLength);
maybeCompact(cx, map, mapLength);
}
void DictionaryPropMap::maybeCompact(JSContext* cx,
MutableHandle<DictionaryPropMap*> map,
uint32_t* mapLength) {
// If there are no holes, there's nothing to compact.
if (map->holeCount_ == 0) {
return;
}
JS::AutoCheckCannotGC nogc;
PropMapTable* table = map->asLinked()->ensureTable(cx, nogc);
if (!table) {
// Compacting is optional so just return.
cx->recoverFromOutOfMemory();
return;
}
// Heuristic: only compact if the number of holes >= the number of (non-hole)
// entries.
if (map->holeCount_ < table->entryCount()) {
return;
}
// Add all dictionary maps to a Vector so that we can iterate over them in
// reverse order (property definition order). If appending to the Vector OOMs,
// just return because compacting is optional.
Vector<DictionaryPropMap*, 32, SystemAllocPolicy> maps;
for (DictionaryPropMap* curMap = map; curMap; curMap = curMap->previous()) {
if (!maps.append(curMap)) {
return;
}
}
// Use two cursors: readMapCursor/readIndexCursor iterates over all properties
// starting at the first one, to search for the next non-hole entry.
// writeMapCursor/writeIndexCursor is used to write all non-hole keys.
//
// At the start of the loop, these cursors point to the next property slot to
// read/write.
size_t readMapCursorVectorIndex = maps.length() - 1;
DictionaryPropMap* readMapCursor = maps[readMapCursorVectorIndex];
uint32_t readIndexCursor = 0;
size_t writeMapCursorVectorIndex = readMapCursorVectorIndex;
DictionaryPropMap* writeMapCursor = readMapCursor;
uint32_t writeIndexCursor = 0;
mozilla::DebugOnly<uint32_t> numHoles = 0;
while (true) {
if (readMapCursor->hasKey(readIndexCursor)) {
// Found a non-hole entry, copy it to its new position and update the
// PropMapTable to point to this new entry. Only do this if the read and
// write positions are different from each other.
if (readMapCursor != writeMapCursor ||
readIndexCursor != writeIndexCursor) {
PropertyKey key = readMapCursor->getKey(readIndexCursor);
auto p = table->lookupRaw(key);
MOZ_ASSERT(p);
MOZ_ASSERT(p->map() == readMapCursor);
MOZ_ASSERT(p->index() == readIndexCursor);
writeMapCursor->setKey(writeIndexCursor, key);
writeMapCursor->linkedData_.propInfos[writeIndexCursor] =
readMapCursor->linkedData_.propInfos[readIndexCursor];
PropMapAndIndex newEntry(writeMapCursor, writeIndexCursor);
table->replaceEntry(p, key, newEntry);
}
// Advance the write cursor.
writeIndexCursor++;
if (writeIndexCursor == PropMap::Capacity) {
MOZ_ASSERT(writeMapCursorVectorIndex > 0);
writeMapCursorVectorIndex--;
writeMapCursor = maps[writeMapCursorVectorIndex];
writeIndexCursor = 0;
}
} else {
numHoles++;
}
// Advance the read cursor. If there are no more maps to read from, we're
// done.
readIndexCursor++;
if (readIndexCursor == PropMap::Capacity) {
if (readMapCursorVectorIndex == 0) {
break;
}
readMapCursorVectorIndex--;
readMapCursor = maps[readMapCursorVectorIndex];
readIndexCursor = 0;
}
}
// Sanity check: the read cursor skipped holes between properties and holes
// at the end of the last map (these are not included in holeCount_).
MOZ_ASSERT(map->holeCount_ + (PropMap::Capacity - *mapLength) == numHoles);
// The write cursor points to the next available slot. If this is at the start
// of a new map, use the previous map (which must be full) instead.
if (writeIndexCursor == 0 && writeMapCursor->previous()) {
writeMapCursor = writeMapCursor->previous();
*mapLength = PropMap::Capacity;
} else {
*mapLength = writeIndexCursor;
}
// Ensure the last map does not have any keys in [mapLength, Capacity).
for (uint32_t i = *mapLength; i < PropMap::Capacity; i++) {
writeMapCursor->clearProperty(i);
}
if (writeMapCursor != map) {
map->handOffLastMapStateTo(writeMapCursor);
map.set(writeMapCursor);
}
map->holeCount_ = 0;
MOZ_ASSERT(*mapLength <= PropMap::Capacity);
MOZ_ASSERT_IF(*mapLength == 0, !map->previous());
MOZ_ASSERT_IF(!map->previous(), table->entryCount() == *mapLength);
}
void SharedPropMap::fixupAfterMovingGC() {
SharedChildrenPtr& childrenRef = treeDataRef().children;
if (childrenRef.isNone()) {
return;
}
if (!hasChildrenSet()) {
SharedPropMapAndIndex child = childrenRef.toSingleChild();
if (gc::IsForwarded(child.map())) {
child = SharedPropMapAndIndex(gc::Forwarded(child.map()), child.index());
childrenRef.setSingleChild(child);
}
return;
}
SharedChildrenSet* set = childrenRef.toChildrenSet();
for (SharedChildrenSet::Enum e(*set); !e.empty(); e.popFront()) {
SharedPropMapAndIndex child = e.front();
if (IsForwarded(child.map())) {
child = SharedPropMapAndIndex(Forwarded(child.map()), child.index());
e.mutableFront() = child;
}
}
}
void SharedPropMap::removeChild(JS::GCContext* gcx, SharedPropMap* child) {
SharedPropMapAndIndex& parentRef = child->treeDataRef().parent;
MOZ_ASSERT(parentRef.map() == this);
uint32_t index = parentRef.index();
parentRef.setNone();
SharedChildrenPtr& childrenRef = treeDataRef().children;
MOZ_ASSERT(!childrenRef.isNone());
if (!hasChildrenSet()) {
MOZ_ASSERT(childrenRef.toSingleChild().map() == child);
MOZ_ASSERT(childrenRef.toSingleChild().index() == index);
childrenRef.setNone();
return;
}
SharedChildrenSet* set = childrenRef.toChildrenSet();
{
uint32_t nextIndex = SharedPropMap::indexOfNextProperty(index);
SharedChildrenHasher::Lookup lookup(
child->getPropertyInfoWithKey(nextIndex), index);
auto p = set->lookup(lookup);
MOZ_ASSERT(p, "Child must be in children set");
set->remove(p);
}
MOZ_ASSERT(set->count() >= 1);
if (set->count() == 1) {
// Convert from set form back to single child form.
SharedChildrenSet::Range r = set->all();
SharedPropMapAndIndex remainingChild = r.front();
childrenRef.setSingleChild(remainingChild);
clearHasChildrenSet();
gcx->delete_(this, set, MemoryUse::PropMapChildren);
}
}
void LinkedPropMap::purgeTable(JS::GCContext* gcx) {
MOZ_ASSERT(hasTable());
gcx->delete_(this, data_.table, MemoryUse::PropMapTable);
data_.table = nullptr;
}
uint32_t PropMap::approximateEntryCount() const {
// Returns a number that's guaranteed to tbe >= the exact number of properties
// in this map (including previous maps). This is used to reserve space in the
// HashSet when allocating a table for this map.
const PropMap* map = this;
uint32_t count = 0;
JS::AutoCheckCannotGC nogc;
while (true) {
if (!map->hasPrevious()) {
return count + PropMap::Capacity;
}
if (PropMapTable* table = map->asLinked()->maybeTable(nogc)) {
return count + table->entryCount();
}
count += PropMap::Capacity;
map = map->asLinked()->previous();
}
}
bool PropMapTable::init(JSContext* cx, LinkedPropMap* map) {
if (!set_.reserve(map->approximateEntryCount())) {
ReportOutOfMemory(cx);
return false;
}
PropMap* curMap = map;
while (true) {
for (uint32_t i = 0; i < PropMap::Capacity; i++) {
if (curMap->hasKey(i)) {
PropertyKey key = curMap->getKey(i);
set_.putNewInfallible(key, PropMapAndIndex(curMap, i));
}
}
if (!curMap->hasPrevious()) {
break;
}
curMap = curMap->asLinked()->previous();
}
return true;
}
void PropMapTable::trace(JSTracer* trc) {
purgeCache();
for (Set::Enum e(set_); !e.empty(); e.popFront()) {
PropMap* map = e.front().map();
TraceManuallyBarrieredEdge(trc, &map, "PropMapTable map");
if (map != e.front().map()) {
e.mutableFront() = PropMapAndIndex(map, e.front().index());
}
}
}
#ifdef JSGC_HASH_TABLE_CHECKS
void PropMapTable::checkAfterMovingGC() {
for (Set::Enum e(set_); !e.empty(); e.popFront()) {
PropMap* map = e.front().map();
MOZ_ASSERT(map);
CheckGCThingAfterMovingGC(map);
PropertyKey key = map->getKey(e.front().index());
MOZ_RELEASE_ASSERT(!key.isVoid());
auto p = lookupRaw(key);
MOZ_RELEASE_ASSERT(p.found() && *p == e.front());
}
}
#endif
#ifdef DEBUG
bool LinkedPropMap::canSkipMarkingTable() {
if (!hasTable()) {
return true;
}
PropMapTable* table = data_.table;
uint32_t count = 0;
PropMap* map = this;
while (true) {
for (uint32_t i = 0; i < Capacity; i++) {
if (map->hasKey(i)) {
PropertyKey key = map->getKey(i);
PropMapTable::Ptr p = table->readonlyThreadsafeLookup(key);
MOZ_ASSERT(*p == PropMapAndIndex(map, i));
count++;
}
}
if (!map->hasPrevious()) {
break;
}
map = map->asLinked()->previous();
}
return count == table->entryCount();
}
#endif
bool LinkedPropMap::createTable(JSContext* cx) {
MOZ_ASSERT(canHaveTable());
MOZ_ASSERT(!hasTable());
UniquePtr<PropMapTable> table = cx->make_unique<PropMapTable>();
if (!table) {
return false;
}
if (!table->init(cx, this)) {
return false;
}
data_.table = table.release();
// TODO: The contents of PropMapTable is not currently tracked, only the
// object itself.
AddCellMemory(this, sizeof(PropMapTable), MemoryUse::PropMapTable);
return true;
}
#ifdef DEBUG
void PropMap::dump(js::GenericPrinter& out) const {
out.printf("map @ 0x%p\n", this);
out.printf("previous: 0x%p\n",
hasPrevious() ? asLinked()->previous() : nullptr);
if (canHaveTable()) {
out.printf("table: 0x%p\n", asLinked()->data_.table);
} else {
out.printf("table: (too small for table)\n");
}
if (isShared()) {
out.printf("type: shared\n");
out.printf(" compact: %s\n", isCompact() ? "yes" : "no");
SharedPropMapAndIndex parent = asShared()->treeDataRef().parent;
if (parent.isNone()) {
out.printf(" parent: (none)\n");
} else {
out.printf(" parent: 0x%p [%u]\n", parent.map(), parent.index());
}
} else {
const DictionaryPropMap* dictMap = asDictionary();
out.printf("type: dictionary\n");
out.printf(" freeList: %u\n", dictMap->freeList_);
out.printf(" holeCount: %u\n", dictMap->holeCount_);
}
out.printf("properties:\n");
for (uint32_t i = 0; i < Capacity; i++) {
out.printf(" %u: ", i);
if (!hasKey(i)) {
out.printf("(empty)\n");
continue;
}
PropertyKey key = getKey(i);
if (key.isInt()) {
out.printf("[%d]", key.toInt());
} else if (key.isAtom()) {
EscapedStringPrinter(out, key.toAtom(), '"');
} else {
MOZ_ASSERT(key.isSymbol());
key.toSymbol()->dump(out);
}
PropertyInfo prop = getPropertyInfo(i);
out.printf(" slot %u flags 0x%x ", prop.maybeSlot(), prop.flags().toRaw());
if (!prop.flags().isEmpty()) {
bool first = true;
auto dumpFlag = [&](PropertyFlag flag, const char* name) {
if (!prop.flags().hasFlag(flag)) {
return;
}
if (!first) {
out.putChar(' ');
}
out.put(name);
first = false;
};
out.putChar('(');
dumpFlag(PropertyFlag::Enumerable, "enumerable");
dumpFlag(PropertyFlag::Configurable, "configurable");
dumpFlag(PropertyFlag::Writable, "writable");
dumpFlag(PropertyFlag::AccessorProperty, "accessor");
dumpFlag(PropertyFlag::CustomDataProperty, "custom-data");
out.putChar(')');
}
out.putChar('\n');
}
}
void PropMap::dump() const {
Fprinter out(stderr);
dump(out);
}
void PropMap::checkConsistency(NativeObject* obj) const {
const uint32_t mapLength = obj->shape()->propMapLength();
MOZ_ASSERT(mapLength <= PropMap::Capacity);
JS::AutoCheckCannotGC nogc;
if (isDictionary()) {
// Check dictionary slot free list.
for (uint32_t fslot = asDictionary()->freeList();
fslot != SHAPE_INVALID_SLOT;
fslot = obj->getSlot(fslot).toPrivateUint32()) {
MOZ_ASSERT(fslot < obj->slotSpan());
}
auto* table = asLinked()->maybeTable(nogc);
const DictionaryPropMap* curMap = asDictionary();
uint32_t numHoles = 0;
do {
// Some fields must only be set for the last dictionary map.
if (curMap != this) {
MOZ_ASSERT(!curMap->asLinked()->hasTable());
MOZ_ASSERT(curMap->holeCount_ == 0);
MOZ_ASSERT(curMap->freeList_ == SHAPE_INVALID_SLOT);
}
for (uint32_t i = 0; i < PropMap::Capacity; i++) {
if (!curMap->hasKey(i)) {
if (curMap != this || i < mapLength) {
numHoles++;
}
continue;
}
// The last dictionary map must only have keys up to mapLength.
MOZ_ASSERT_IF(curMap == this, i < mapLength);
PropertyInfo prop = curMap->getPropertyInfo(i);
MOZ_ASSERT_IF(prop.hasSlot(), prop.slot() < obj->slotSpan());
// All properties must be in the table.
if (table) {
PropertyKey key = curMap->getKey(i);
auto p = table->lookupRaw(key);
MOZ_ASSERT(p->map() == curMap);
MOZ_ASSERT(p->index() == i);
}
}
curMap = curMap->previous();
} while (curMap);
MOZ_ASSERT(asDictionary()->holeCount_ == numHoles);
return;
}
MOZ_ASSERT(mapLength > 0);
const SharedPropMap* curMap = asShared();
auto* table =
curMap->canHaveTable() ? curMap->asLinked()->maybeTable(nogc) : nullptr;
// Shared maps without a previous map never have a table.
MOZ_ASSERT_IF(!curMap->hasPrevious(), !curMap->canHaveTable());
const SharedPropMap* nextMap = nullptr;
mozilla::Maybe<uint32_t> nextSlot;
while (true) {
// Verify numPreviousMaps is set correctly.
MOZ_ASSERT_IF(nextMap && nextMap->numPreviousMaps() != NumPreviousMapsMax,
curMap->numPreviousMaps() + 1 == nextMap->numPreviousMaps());
MOZ_ASSERT(curMap->hasPrevious() == (curMap->numPreviousMaps() > 0));
// If a previous map also has a table, it must have fewer entries than the
// last map's table.
if (table && curMap != this && curMap->canHaveTable()) {
if (auto* table2 = curMap->asLinked()->maybeTable(nogc)) {
MOZ_ASSERT(table2->entryCount() < table->entryCount());
}
}
for (int32_t i = PropMap::Capacity - 1; i >= 0; i--) {
uint32_t index = uint32_t(i);
// Only the last map can have holes, for entries following mapLength.
if (!curMap->hasKey(index)) {
MOZ_ASSERT(index > 0);
MOZ_ASSERT(curMap == this);
MOZ_ASSERT(index >= mapLength);
continue;
}
// Check slot numbers are within slot span and never decreasing.
PropertyInfo prop = curMap->getPropertyInfo(i);
if (prop.hasSlot()) {
MOZ_ASSERT_IF((curMap != this || index < mapLength),
prop.slot() < obj->slotSpan());
MOZ_ASSERT_IF(nextSlot.isSome(), *nextSlot >= prop.slot());
nextSlot = mozilla::Some(prop.slot());
}
// All properties must be in the table.
if (table) {
PropertyKey key = curMap->getKey(index);
auto p = table->lookupRaw(key);
MOZ_ASSERT(p->map() == curMap);
MOZ_ASSERT(p->index() == index);
}
}
if (!curMap->hasPrevious()) {
break;
}
nextMap = curMap;
curMap = curMap->asLinked()->previous()->asShared();
}
}
#endif // DEBUG
JS::ubi::Node::Size JS::ubi::Concrete<PropMap>::size(
mozilla::MallocSizeOf mallocSizeOf) const {
Size size = js::gc::Arena::thingSize(get().asTenured().getAllocKind());
size_t children = 0;
size_t tables = 0;
get().addSizeOfExcludingThis(mallocSizeOf, &children, &tables);
return size + children + tables;
}
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