/* -*- 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 #include #include #include #include "PLDHashTable.h" #include "mozilla/HashFunctions.h" #include "mozilla/MathAlgorithms.h" #include "mozilla/OperatorNewExtensions.h" #include "nsAlgorithm.h" #include "nsPointerHashKeys.h" #include "mozilla/Likely.h" #include "mozilla/MemoryReporting.h" #include "mozilla/Maybe.h" #include "mozilla/ChaosMode.h" using namespace mozilla; #ifdef DEBUG class AutoReadOp { Checker& mChk; public: explicit AutoReadOp(Checker& aChk) : mChk(aChk) { mChk.StartReadOp(); } ~AutoReadOp() { mChk.EndReadOp(); } }; class AutoWriteOp { Checker& mChk; public: explicit AutoWriteOp(Checker& aChk) : mChk(aChk) { mChk.StartWriteOp(); } ~AutoWriteOp() { mChk.EndWriteOp(); } }; class AutoIteratorRemovalOp { Checker& mChk; public: explicit AutoIteratorRemovalOp(Checker& aChk) : mChk(aChk) { mChk.StartIteratorRemovalOp(); } ~AutoIteratorRemovalOp() { mChk.EndIteratorRemovalOp(); } }; class AutoDestructorOp { Checker& mChk; public: explicit AutoDestructorOp(Checker& aChk) : mChk(aChk) { mChk.StartDestructorOp(); } ~AutoDestructorOp() { mChk.EndDestructorOp(); } }; #endif /* static */ PLDHashNumber PLDHashTable::HashStringKey(const void* aKey) { return HashString(static_cast(aKey)); } /* static */ PLDHashNumber PLDHashTable::HashVoidPtrKeyStub(const void* aKey) { return nsPtrHashKey::HashKey(aKey); } /* static */ bool PLDHashTable::MatchEntryStub(const PLDHashEntryHdr* aEntry, const void* aKey) { const PLDHashEntryStub* stub = (const PLDHashEntryStub*)aEntry; return stub->key == aKey; } /* static */ bool PLDHashTable::MatchStringKey(const PLDHashEntryHdr* aEntry, const void* aKey) { const PLDHashEntryStub* stub = (const PLDHashEntryStub*)aEntry; // XXX tolerate null keys on account of sloppy Mozilla callers. return stub->key == aKey || (stub->key && aKey && strcmp((const char*)stub->key, (const char*)aKey) == 0); } /* static */ void PLDHashTable::MoveEntryStub(PLDHashTable* aTable, const PLDHashEntryHdr* aFrom, PLDHashEntryHdr* aTo) { memcpy(aTo, aFrom, aTable->mEntrySize); } /* static */ void PLDHashTable::ClearEntryStub(PLDHashTable* aTable, PLDHashEntryHdr* aEntry) { memset(aEntry, 0, aTable->mEntrySize); } static const PLDHashTableOps gStubOps = { PLDHashTable::HashVoidPtrKeyStub, PLDHashTable::MatchEntryStub, PLDHashTable::MoveEntryStub, PLDHashTable::ClearEntryStub, nullptr}; /* static */ const PLDHashTableOps* PLDHashTable::StubOps() { return &gStubOps; } static bool SizeOfEntryStore(uint32_t aCapacity, uint32_t aEntrySize, uint32_t* aNbytes) { uint32_t slotSize = aEntrySize + sizeof(PLDHashNumber); uint64_t nbytes64 = uint64_t(aCapacity) * uint64_t(slotSize); *aNbytes = aCapacity * slotSize; return uint64_t(*aNbytes) == nbytes64; // returns false on overflow } // Compute max and min load numbers (entry counts). We have a secondary max // that allows us to overload a table reasonably if it cannot be grown further // (i.e. if ChangeTable() fails). The table slows down drastically if the // secondary max is too close to 1, but 0.96875 gives only a slight slowdown // while allowing 1.3x more elements. static inline uint32_t MaxLoad(uint32_t aCapacity) { return aCapacity - (aCapacity >> 2); // == aCapacity * 0.75 } static inline uint32_t MaxLoadOnGrowthFailure(uint32_t aCapacity) { return aCapacity - (aCapacity >> 5); // == aCapacity * 0.96875 } static inline uint32_t MinLoad(uint32_t aCapacity) { return aCapacity >> 2; // == aCapacity * 0.25 } // Compute the minimum capacity (and the Log2 of that capacity) for a table // containing |aLength| elements while respecting the following contraints: // - table must be at most 75% full; // - capacity must be a power of two; // - capacity cannot be too small. static inline void BestCapacity(uint32_t aLength, uint32_t* aCapacityOut, uint32_t* aLog2CapacityOut) { // Callers should ensure this is true. MOZ_ASSERT(aLength <= PLDHashTable::kMaxInitialLength); // Compute the smallest capacity allowing |aLength| elements to be inserted // without rehashing. uint32_t capacity = (aLength * 4 + (3 - 1)) / 3; // == ceil(aLength * 4 / 3) if (capacity < PLDHashTable::kMinCapacity) { capacity = PLDHashTable::kMinCapacity; } // Round up capacity to next power-of-two. uint32_t log2 = CeilingLog2(capacity); capacity = 1u << log2; MOZ_ASSERT(capacity <= PLDHashTable::kMaxCapacity); *aCapacityOut = capacity; *aLog2CapacityOut = log2; } /* static */ MOZ_ALWAYS_INLINE uint32_t PLDHashTable::HashShift(uint32_t aEntrySize, uint32_t aLength) { if (aLength > kMaxInitialLength) { MOZ_CRASH("Initial length is too large"); } uint32_t capacity, log2; BestCapacity(aLength, &capacity, &log2); uint32_t nbytes; if (!SizeOfEntryStore(capacity, aEntrySize, &nbytes)) { MOZ_CRASH("Initial entry store size is too large"); } // Compute the hashShift value. return kPLDHashNumberBits - log2; } PLDHashTable::PLDHashTable(const PLDHashTableOps* aOps, uint32_t aEntrySize, uint32_t aLength) : mOps(recordreplay::GeneratePLDHashTableCallbacks(aOps)), mEntryStore(), mGeneration(0), mHashShift(HashShift(aEntrySize, aLength)), mEntrySize(aEntrySize), mEntryCount(0), mRemovedCount(0) #ifdef DEBUG , mChecker() #endif { // An entry size greater than 0xff is unlikely, but let's check anyway. If // you hit this, your hashtable would waste lots of space for unused entries // and you should change your hash table's entries to pointers. if (aEntrySize != uint32_t(mEntrySize)) { MOZ_CRASH("Entry size is too large"); } } PLDHashTable& PLDHashTable::operator=(PLDHashTable&& aOther) { if (this == &aOther) { return *this; } // |mOps| and |mEntrySize| are required to stay the same, they're // conceptually part of the type -- indeed, if PLDHashTable was a templated // type like nsTHashtable, they *would* be part of the type -- so it only // makes sense to assign in cases where they match. An exception is when we // are recording or replaying the execution, in which case custom ops are // generated for each table. MOZ_RELEASE_ASSERT(mOps == aOther.mOps || !mOps || recordreplay::IsRecordingOrReplaying()); MOZ_RELEASE_ASSERT(mEntrySize == aOther.mEntrySize || !mEntrySize); // Reconstruct |this|. const PLDHashTableOps* ops = recordreplay::UnwrapPLDHashTableCallbacks(aOther.mOps); this->~PLDHashTable(); new (KnownNotNull, this) PLDHashTable(ops, aOther.mEntrySize, 0); // Move non-const pieces over. mHashShift = std::move(aOther.mHashShift); mEntryCount = std::move(aOther.mEntryCount); mRemovedCount = std::move(aOther.mRemovedCount); mEntryStore.Set(aOther.mEntryStore.Get(), &mGeneration); #ifdef DEBUG mChecker = std::move(aOther.mChecker); #endif recordreplay::MovePLDHashTableContents(aOther.mOps, mOps); // Clear up |aOther| so its destruction will be a no-op and it reports being // empty. { #ifdef DEBUG AutoDestructorOp op(mChecker); #endif aOther.mEntryCount = 0; aOther.mEntryStore.Set(nullptr, &aOther.mGeneration); } return *this; } PLDHashNumber PLDHashTable::Hash1(PLDHashNumber aHash0) const { return aHash0 >> mHashShift; } void PLDHashTable::Hash2(PLDHashNumber aHash0, uint32_t& aHash2Out, uint32_t& aSizeMaskOut) const { uint32_t sizeLog2 = kPLDHashNumberBits - mHashShift; uint32_t sizeMask = (PLDHashNumber(1) << sizeLog2) - 1; aSizeMaskOut = sizeMask; // The incoming aHash0 always has the low bit unset (since we leave it // free for the collision flag), and should have reasonably random // data in the other 31 bits. We used the high bits of aHash0 for // Hash1, so we use the low bits here. If the table size is large, // the bits we use may overlap, but that's still more random than // filling with 0s. // // Double hashing needs the second hash code to be relatively prime to table // size, so we simply make hash2 odd. // // This also conveniently covers up the fact that we have the low bit // unset since aHash0 has the low bit unset. aHash2Out = (aHash0 & sizeMask) | 1; } // Reserve mKeyHash 0 for free entries and 1 for removed-entry sentinels. Note // that a removed-entry sentinel need be stored only if the removed entry had // a colliding entry added after it. Therefore we can use 1 as the collision // flag in addition to the removed-entry sentinel value. Multiplicative hash // uses the high order bits of mKeyHash, so this least-significant reservation // should not hurt the hash function's effectiveness much. // Match an entry's mKeyHash against an unstored one computed from a key. /* static */ bool PLDHashTable::MatchSlotKeyhash(Slot& aSlot, const PLDHashNumber aKeyHash) { return (aSlot.KeyHash() & ~kCollisionFlag) == aKeyHash; } // Compute the address of the indexed entry in table. auto PLDHashTable::SlotForIndex(uint32_t aIndex) const -> Slot { return mEntryStore.SlotForIndex(aIndex, mEntrySize, CapacityFromHashShift()); } PLDHashTable::~PLDHashTable() { #ifdef DEBUG AutoDestructorOp op(mChecker); #endif if (!mEntryStore.Get()) { recordreplay::DestroyPLDHashTableCallbacks(mOps); return; } // Clear any remaining live entries. mEntryStore.ForEachSlot(Capacity(), mEntrySize, [&](const Slot& aSlot) { if (aSlot.IsLive()) { mOps->clearEntry(this, aSlot.ToEntry()); } }); recordreplay::DestroyPLDHashTableCallbacks(mOps); // Entry storage is freed last, by ~EntryStore(). } void PLDHashTable::ClearAndPrepareForLength(uint32_t aLength) { // Get these values before the destructor clobbers them. const PLDHashTableOps* ops = recordreplay::UnwrapPLDHashTableCallbacks(mOps); uint32_t entrySize = mEntrySize; this->~PLDHashTable(); new (KnownNotNull, this) PLDHashTable(ops, entrySize, aLength); } void PLDHashTable::Clear() { ClearAndPrepareForLength(kDefaultInitialLength); } // If |Reason| is |ForAdd|, the return value is always non-null and it may be // a previously-removed entry. If |Reason| is |ForSearchOrRemove|, the return // value is null on a miss, and will never be a previously-removed entry on a // hit. This distinction is a bit grotty but this function is hot enough that // these differences are worthwhile. (It's also hot enough that // MOZ_ALWAYS_INLINE makes a significant difference.) template MOZ_ALWAYS_INLINE auto PLDHashTable::SearchTable(const void* aKey, PLDHashNumber aKeyHash, Success&& aSuccess, Failure&& aFailure) const { MOZ_ASSERT(mEntryStore.Get()); NS_ASSERTION(!(aKeyHash & kCollisionFlag), "!(aKeyHash & kCollisionFlag)"); // Compute the primary hash address. PLDHashNumber hash1 = Hash1(aKeyHash); Slot slot = SlotForIndex(hash1); // Miss: return space for a new entry. if (slot.IsFree()) { return (Reason == ForAdd) ? aSuccess(slot) : aFailure(); } // Hit: return entry. PLDHashMatchEntry matchEntry = mOps->matchEntry; if (MatchSlotKeyhash(slot, aKeyHash)) { PLDHashEntryHdr* e = slot.ToEntry(); if (matchEntry(e, aKey)) { return aSuccess(slot); } } // Collision: double hash. PLDHashNumber hash2; uint32_t sizeMask; Hash2(aKeyHash, hash2, sizeMask); // Save the first removed entry slot so Add() can recycle it. (Only used // if Reason==ForAdd.) Maybe firstRemoved; for (;;) { if (Reason == ForAdd && !firstRemoved) { if (MOZ_UNLIKELY(slot.IsRemoved())) { firstRemoved.emplace(slot); } else { slot.MarkColliding(); } } hash1 -= hash2; hash1 &= sizeMask; slot = SlotForIndex(hash1); if (slot.IsFree()) { if (Reason != ForAdd) { return aFailure(); } return aSuccess(firstRemoved.refOr(slot)); } if (MatchSlotKeyhash(slot, aKeyHash)) { PLDHashEntryHdr* e = slot.ToEntry(); if (matchEntry(e, aKey)) { return aSuccess(slot); } } } // NOTREACHED return aFailure(); } // This is a copy of SearchTable(), used by ChangeTable(), hardcoded to // 1. assume |Reason| is |ForAdd|, // 2. assume that |aKey| will never match an existing entry, and // 3. assume that no entries have been removed from the current table // structure. // Avoiding the need for |aKey| means we can avoid needing a way to map entries // to keys, which means callers can use complex key types more easily. MOZ_ALWAYS_INLINE auto PLDHashTable::FindFreeSlot(PLDHashNumber aKeyHash) const -> Slot { MOZ_ASSERT(mEntryStore.Get()); NS_ASSERTION(!(aKeyHash & kCollisionFlag), "!(aKeyHash & kCollisionFlag)"); // Compute the primary hash address. PLDHashNumber hash1 = Hash1(aKeyHash); Slot slot = SlotForIndex(hash1); // Miss: return space for a new entry. if (slot.IsFree()) { return slot; } // Collision: double hash. PLDHashNumber hash2; uint32_t sizeMask; Hash2(aKeyHash, hash2, sizeMask); for (;;) { MOZ_ASSERT(!slot.IsRemoved()); slot.MarkColliding(); hash1 -= hash2; hash1 &= sizeMask; slot = SlotForIndex(hash1); if (slot.IsFree()) { return slot; } } // NOTREACHED } bool PLDHashTable::ChangeTable(int32_t aDeltaLog2) { MOZ_ASSERT(mEntryStore.Get()); // Look, but don't touch, until we succeed in getting new entry store. int32_t oldLog2 = kPLDHashNumberBits - mHashShift; int32_t newLog2 = oldLog2 + aDeltaLog2; uint32_t newCapacity = 1u << newLog2; if (newCapacity > kMaxCapacity) { return false; } uint32_t nbytes; if (!SizeOfEntryStore(newCapacity, mEntrySize, &nbytes)) { return false; // overflowed } char* newEntryStore = (char*)calloc(1, nbytes); if (!newEntryStore) { return false; } // We can't fail from here on, so update table parameters. mHashShift = kPLDHashNumberBits - newLog2; mRemovedCount = 0; // Assign the new entry store to table. char* oldEntryStore = mEntryStore.Get(); mEntryStore.Set(newEntryStore, &mGeneration); PLDHashMoveEntry moveEntry = mOps->moveEntry; // Copy only live entries, leaving removed ones behind. uint32_t oldCapacity = 1u << oldLog2; EntryStore::ForEachSlot( oldEntryStore, oldCapacity, mEntrySize, [&](const Slot& slot) { if (slot.IsLive()) { const PLDHashNumber key = slot.KeyHash() & ~kCollisionFlag; Slot newSlot = FindFreeSlot(key); MOZ_ASSERT(newSlot.IsFree()); moveEntry(this, slot.ToEntry(), newSlot.ToEntry()); newSlot.SetKeyHash(key); } }); free(oldEntryStore); return true; } MOZ_ALWAYS_INLINE PLDHashNumber PLDHashTable::ComputeKeyHash(const void* aKey) const { MOZ_ASSERT(mEntryStore.Get()); PLDHashNumber keyHash = mozilla::ScrambleHashCode(mOps->hashKey(aKey)); // Avoid 0 and 1 hash codes, they indicate free and removed entries. if (keyHash < 2) { keyHash -= 2; } keyHash &= ~kCollisionFlag; return keyHash; } PLDHashEntryHdr* PLDHashTable::Search(const void* aKey) const { #ifdef DEBUG AutoReadOp op(mChecker); #endif if (!mEntryStore.Get()) { return nullptr; } return SearchTable( aKey, ComputeKeyHash(aKey), [&](Slot& slot) -> PLDHashEntryHdr* { return slot.ToEntry(); }, [&]() -> PLDHashEntryHdr* { return nullptr; }); } PLDHashEntryHdr* PLDHashTable::Add(const void* aKey, const mozilla::fallible_t&) { #ifdef DEBUG AutoWriteOp op(mChecker); #endif // Allocate the entry storage if it hasn't already been allocated. if (!mEntryStore.Get()) { uint32_t nbytes; // We already checked this in the constructor, so it must still be true. MOZ_RELEASE_ASSERT( SizeOfEntryStore(CapacityFromHashShift(), mEntrySize, &nbytes)); mEntryStore.Set((char*)calloc(1, nbytes), &mGeneration); if (!mEntryStore.Get()) { return nullptr; } } // If alpha is >= .75, grow or compress the table. If aKey is already in the // table, we may grow once more than necessary, but only if we are on the // edge of being overloaded. uint32_t capacity = Capacity(); if (mEntryCount + mRemovedCount >= MaxLoad(capacity)) { // Compress if a quarter or more of all entries are removed. int deltaLog2; if (mRemovedCount >= capacity >> 2) { deltaLog2 = 0; } else { deltaLog2 = 1; } // Grow or compress the table. If ChangeTable() fails, allow overloading up // to the secondary max. Once we hit the secondary max, return null. if (!ChangeTable(deltaLog2) && mEntryCount + mRemovedCount >= MaxLoadOnGrowthFailure(capacity)) { return nullptr; } } // Look for entry after possibly growing, so we don't have to add it, // then skip it while growing the table and re-add it after. PLDHashNumber keyHash = ComputeKeyHash(aKey); Slot slot = SearchTable( aKey, keyHash, [&](Slot& found) -> Slot { return found; }, [&]() -> Slot { MOZ_CRASH("Nope"); return Slot(nullptr, nullptr); }); if (!slot.IsLive()) { // Initialize the slot, indicating that it's no longer free. if (slot.IsRemoved()) { mRemovedCount--; keyHash |= kCollisionFlag; } if (mOps->initEntry) { mOps->initEntry(slot.ToEntry(), aKey); } slot.SetKeyHash(keyHash); mEntryCount++; } return slot.ToEntry(); } PLDHashEntryHdr* PLDHashTable::Add(const void* aKey) { PLDHashEntryHdr* entry = Add(aKey, fallible); if (!entry) { if (!mEntryStore.Get()) { // We OOM'd while allocating the initial entry storage. uint32_t nbytes; (void)SizeOfEntryStore(CapacityFromHashShift(), mEntrySize, &nbytes); NS_ABORT_OOM(nbytes); } else { // We failed to resize the existing entry storage, either due to OOM or // because we exceeded the maximum table capacity or size; report it as // an OOM. The multiplication by 2 gets us the size we tried to allocate, // which is double the current size. NS_ABORT_OOM(2 * EntrySize() * EntryCount()); } } return entry; } void PLDHashTable::Remove(const void* aKey) { #ifdef DEBUG AutoWriteOp op(mChecker); #endif if (!mEntryStore.Get()) { return; } PLDHashNumber keyHash = ComputeKeyHash(aKey); SearchTable( aKey, keyHash, [&](Slot& slot) { RawRemove(slot); ShrinkIfAppropriate(); }, [&]() { // Do nothing. }); } void PLDHashTable::RemoveEntry(PLDHashEntryHdr* aEntry) { #ifdef DEBUG AutoWriteOp op(mChecker); #endif RawRemove(aEntry); ShrinkIfAppropriate(); } void PLDHashTable::RawRemove(PLDHashEntryHdr* aEntry) { Slot slot(mEntryStore.SlotForPLDHashEntry(aEntry, Capacity(), mEntrySize)); RawRemove(slot); } void PLDHashTable::RawRemove(Slot& aSlot) { // Unfortunately, we can only do weak checking here. That's because // RawRemove() can be called legitimately while an Enumerate() call is // active, which doesn't fit well into how Checker's mState variable works. MOZ_ASSERT(mChecker.IsWritable()); MOZ_ASSERT(mEntryStore.Get()); MOZ_ASSERT(aSlot.IsLive()); // Load keyHash first in case clearEntry() goofs it. PLDHashEntryHdr* entry = aSlot.ToEntry(); PLDHashNumber keyHash = aSlot.KeyHash(); mOps->clearEntry(this, entry); if (keyHash & kCollisionFlag) { aSlot.MarkRemoved(); mRemovedCount++; } else { aSlot.MarkFree(); } mEntryCount--; } // Shrink or compress if a quarter or more of all entries are removed, or if the // table is underloaded according to the minimum alpha, and is not minimal-size // already. void PLDHashTable::ShrinkIfAppropriate() { uint32_t capacity = Capacity(); if (mRemovedCount >= capacity >> 2 || (capacity > kMinCapacity && mEntryCount <= MinLoad(capacity))) { uint32_t log2; BestCapacity(mEntryCount, &capacity, &log2); int32_t deltaLog2 = log2 - (kPLDHashNumberBits - mHashShift); MOZ_ASSERT(deltaLog2 <= 0); (void)ChangeTable(deltaLog2); } } size_t PLDHashTable::ShallowSizeOfExcludingThis( MallocSizeOf aMallocSizeOf) const { #ifdef DEBUG AutoReadOp op(mChecker); #endif return aMallocSizeOf(mEntryStore.Get()); } size_t PLDHashTable::ShallowSizeOfIncludingThis( MallocSizeOf aMallocSizeOf) const { return aMallocSizeOf(this) + ShallowSizeOfExcludingThis(aMallocSizeOf); } PLDHashTable::Iterator::Iterator(Iterator&& aOther) : mTable(aOther.mTable), mCurrent(aOther.mCurrent), mNexts(aOther.mNexts), mNextsLimit(aOther.mNextsLimit), mHaveRemoved(aOther.mHaveRemoved), mEntrySize(aOther.mEntrySize) { // No need to change |mChecker| here. aOther.mTable = nullptr; // We don't really have the concept of a null slot, so leave mCurrent. aOther.mNexts = 0; aOther.mNextsLimit = 0; aOther.mHaveRemoved = false; aOther.mEntrySize = 0; } PLDHashTable::Iterator::Iterator(PLDHashTable* aTable) : mTable(aTable), mCurrent(mTable->mEntryStore.SlotForIndex(0, mTable->mEntrySize, mTable->Capacity())), mNexts(0), mNextsLimit(mTable->EntryCount()), mHaveRemoved(false), mEntrySize(aTable->mEntrySize) { #ifdef DEBUG mTable->mChecker.StartReadOp(); #endif if (ChaosMode::isActive(ChaosFeature::HashTableIteration) && mTable->Capacity() > 0) { // Start iterating at a random entry. It would be even more chaotic to // iterate in fully random order, but that's harder. uint32_t capacity = mTable->CapacityFromHashShift(); uint32_t i = ChaosMode::randomUint32LessThan(capacity); mCurrent = mTable->mEntryStore.SlotForIndex(i, mTable->mEntrySize, capacity); } // Advance to the first live entry, if there is one. if (!Done() && IsOnNonLiveEntry()) { MoveToNextLiveEntry(); } } PLDHashTable::Iterator::Iterator(PLDHashTable* aTable, EndIteratorTag aTag) : mTable(aTable), mCurrent(mTable->mEntryStore.SlotForIndex(0, mTable->mEntrySize, mTable->Capacity())), mNexts(mTable->EntryCount()), mNextsLimit(mTable->EntryCount()), mHaveRemoved(false), mEntrySize(aTable->mEntrySize) { #ifdef DEBUG mTable->mChecker.StartReadOp(); #endif MOZ_ASSERT(Done()); } PLDHashTable::Iterator::Iterator(const Iterator& aOther) : mTable(aOther.mTable), mCurrent(aOther.mCurrent), mNexts(aOther.mNexts), mNextsLimit(aOther.mNextsLimit), mHaveRemoved(aOther.mHaveRemoved), mEntrySize(aOther.mEntrySize) { // TODO: Is this necessary? MOZ_ASSERT(!mHaveRemoved); #ifdef DEBUG mTable->mChecker.StartReadOp(); #endif } PLDHashTable::Iterator::~Iterator() { if (mTable) { if (mHaveRemoved) { mTable->ShrinkIfAppropriate(); } #ifdef DEBUG mTable->mChecker.EndReadOp(); #endif } } MOZ_ALWAYS_INLINE bool PLDHashTable::Iterator::IsOnNonLiveEntry() const { MOZ_ASSERT(!Done()); return !mCurrent.IsLive(); } void PLDHashTable::Iterator::Next() { MOZ_ASSERT(!Done()); mNexts++; // Advance to the next live entry, if there is one. if (!Done()) { MoveToNextLiveEntry(); } } MOZ_ALWAYS_INLINE void PLDHashTable::Iterator::MoveToNextLiveEntry() { // Chaos mode requires wraparound to cover all possible entries, so we can't // simply move to the next live entry and stop when we hit the end of the // entry store. But we don't want to introduce extra branches into our inner // loop. So we are going to exploit the structure of the entry store in this // method to implement an efficient inner loop. // // The idea is that since we are really only iterating through the stored // hashes and because we know that there are a power-of-two number of // hashes, we can use masking to implement the wraparound for us. This // method does have the downside of needing to recalculate where the // associated entry is once we've found it, but that seems OK. // Our current slot and its associated hash. Slot slot = mCurrent; PLDHashNumber* p = slot.HashPtr(); const uint32_t capacity = mTable->CapacityFromHashShift(); const uint32_t mask = capacity - 1; auto hashes = reinterpret_cast(mTable->mEntryStore.Get()); uint32_t slotIndex = p - hashes; do { slotIndex = (slotIndex + 1) & mask; } while (!Slot::IsLiveHash(hashes[slotIndex])); // slotIndex now indicates where a live slot is. Rematerialize the entry // and the slot. auto entries = reinterpret_cast(&hashes[capacity]); char* entryPtr = entries + slotIndex * mEntrySize; auto entry = reinterpret_cast(entryPtr); mCurrent = Slot(entry, &hashes[slotIndex]); } void PLDHashTable::Iterator::Remove() { mTable->RawRemove(mCurrent); mHaveRemoved = true; } #ifdef DEBUG void PLDHashTable::MarkImmutable() { mChecker.SetNonWritable(); } #endif