/* * Copyright 2012-present Facebook, Inc. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef FOLLY_ATOMICHASHMAP_H_ #error "This should only be included by AtomicHashMap.h" #endif #include namespace folly { // AtomicHashMap constructor -- Atomic wrapper that allows growth // This class has a lot of overhead (184 Bytes) so only use for big maps template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::AtomicHashMap(size_t finalSizeEst, const Config& config) : kGrowthFrac_( config.growthFactor < 0 ? 1.0f - config.maxLoadFactor : config.growthFactor) { CHECK(config.maxLoadFactor > 0.0f && config.maxLoadFactor < 1.0f); subMaps_[0].store( SubMap::create(finalSizeEst, config).release(), std::memory_order_relaxed); auto subMapCount = kNumSubMaps_; FOR_EACH_RANGE (i, 1, subMapCount) { subMaps_[i].store(nullptr, std::memory_order_relaxed); } numMapsAllocated_.store(1, std::memory_order_relaxed); } // emplace -- template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> template < typename LookupKeyT, typename LookupHashFcn, typename LookupEqualFcn, typename LookupKeyToKeyFcn, typename... ArgTs> std::pair< typename AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::iterator, bool> AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::emplace(LookupKeyT k, ArgTs&&... vCtorArgs) { SimpleRetT ret = insertInternal< LookupKeyT, LookupHashFcn, LookupEqualFcn, LookupKeyToKeyFcn>(k, std::forward(vCtorArgs)...); SubMap* subMap = subMaps_[ret.i].load(std::memory_order_relaxed); return std::make_pair( iterator(this, ret.i, subMap->makeIter(ret.j)), ret.success); } // insertInternal -- Allocates new sub maps as existing ones fill up. template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> template < typename LookupKeyT, typename LookupHashFcn, typename LookupEqualFcn, typename LookupKeyToKeyFcn, typename... ArgTs> typename AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::SimpleRetT AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::insertInternal(LookupKeyT key, ArgTs&&... vCtorArgs) { beginInsertInternal: auto nextMapIdx = // this maintains our state numMapsAllocated_.load(std::memory_order_acquire); typename SubMap::SimpleRetT ret; FOR_EACH_RANGE (i, 0, nextMapIdx) { // insert in each map successively. If one succeeds, we're done! SubMap* subMap = subMaps_[i].load(std::memory_order_relaxed); ret = subMap->template insertInternal< LookupKeyT, LookupHashFcn, LookupEqualFcn, LookupKeyToKeyFcn>(key, std::forward(vCtorArgs)...); if (ret.idx == subMap->capacity_) { continue; // map is full, so try the next one } // Either collision or success - insert in either case return SimpleRetT(i, ret.idx, ret.success); } // If we made it this far, all maps are full and we need to try to allocate // the next one. SubMap* primarySubMap = subMaps_[0].load(std::memory_order_relaxed); if (nextMapIdx >= kNumSubMaps_ || primarySubMap->capacity_ * kGrowthFrac_ < 1.0) { // Can't allocate any more sub maps. throw AtomicHashMapFullError(); } if (tryLockMap(nextMapIdx)) { // Alloc a new map and shove it in. We can change whatever // we want because other threads are waiting on us... size_t numCellsAllocated = (size_t)( primarySubMap->capacity_ * std::pow(1.0 + kGrowthFrac_, nextMapIdx - 1)); size_t newSize = size_t(numCellsAllocated * kGrowthFrac_); DCHECK( subMaps_[nextMapIdx].load(std::memory_order_relaxed) == (SubMap*)kLockedPtr_); // create a new map using the settings stored in the first map Config config; config.emptyKey = primarySubMap->kEmptyKey_; config.lockedKey = primarySubMap->kLockedKey_; config.erasedKey = primarySubMap->kErasedKey_; config.maxLoadFactor = primarySubMap->maxLoadFactor(); config.entryCountThreadCacheSize = primarySubMap->getEntryCountThreadCacheSize(); subMaps_[nextMapIdx].store( SubMap::create(newSize, config).release(), std::memory_order_relaxed); // Publish the map to other threads. numMapsAllocated_.fetch_add(1, std::memory_order_release); DCHECK_EQ( nextMapIdx + 1, numMapsAllocated_.load(std::memory_order_relaxed)); } else { // If we lost the race, we'll have to wait for the next map to get // allocated before doing any insertion here. detail::atomic_hash_spin_wait([&] { return nextMapIdx >= numMapsAllocated_.load(std::memory_order_acquire); }); } // Relaxed is ok here because either we just created this map, or we // just did a spin wait with an acquire load on numMapsAllocated_. SubMap* loadedMap = subMaps_[nextMapIdx].load(std::memory_order_relaxed); DCHECK(loadedMap && loadedMap != (SubMap*)kLockedPtr_); ret = loadedMap->insertInternal(key, std::forward(vCtorArgs)...); if (ret.idx != loadedMap->capacity_) { return SimpleRetT(nextMapIdx, ret.idx, ret.success); } // We took way too long and the new map is already full...try again from // the top (this should pretty much never happen). goto beginInsertInternal; } // find -- template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> template typename AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::iterator AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::find(LookupKeyT k) { SimpleRetT ret = findInternal(k); if (!ret.success) { return end(); } SubMap* subMap = subMaps_[ret.i].load(std::memory_order_relaxed); return iterator(this, ret.i, subMap->makeIter(ret.j)); } template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> template typename AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::const_iterator AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::find(LookupKeyT k) const { return const_cast(this) ->find(k); } // findInternal -- template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> template typename AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::SimpleRetT AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::findInternal(const LookupKeyT k) const { SubMap* const primaryMap = subMaps_[0].load(std::memory_order_relaxed); typename SubMap::SimpleRetT ret = primaryMap ->template findInternal(k); if (LIKELY(ret.idx != primaryMap->capacity_)) { return SimpleRetT(0, ret.idx, ret.success); } const unsigned int numMaps = numMapsAllocated_.load(std::memory_order_acquire); FOR_EACH_RANGE (i, 1, numMaps) { // Check each map successively. If one succeeds, we're done! SubMap* thisMap = subMaps_[i].load(std::memory_order_relaxed); ret = thisMap ->template findInternal( k); if (LIKELY(ret.idx != thisMap->capacity_)) { return SimpleRetT(i, ret.idx, ret.success); } } // Didn't find our key... return SimpleRetT(numMaps, 0, false); } // findAtInternal -- see encodeIndex() for details. template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> typename AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::SimpleRetT AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::findAtInternal(uint32_t idx) const { uint32_t subMapIdx, subMapOffset; if (idx & kSecondaryMapBit_) { // idx falls in a secondary map idx &= ~kSecondaryMapBit_; // unset secondary bit subMapIdx = idx >> kSubMapIndexShift_; DCHECK_LT(subMapIdx, numMapsAllocated_.load(std::memory_order_relaxed)); subMapOffset = idx & kSubMapIndexMask_; } else { // idx falls in primary map subMapIdx = 0; subMapOffset = idx; } return SimpleRetT(subMapIdx, subMapOffset, true); } // erase -- template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> typename AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::size_type AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::erase(const KeyT k) { int const numMaps = numMapsAllocated_.load(std::memory_order_acquire); FOR_EACH_RANGE (i, 0, numMaps) { // Check each map successively. If one succeeds, we're done! if (subMaps_[i].load(std::memory_order_relaxed)->erase(k)) { return 1; } } // Didn't find our key... return 0; } // capacity -- summation of capacities of all submaps template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> size_t AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::capacity() const { size_t totalCap(0); int const numMaps = numMapsAllocated_.load(std::memory_order_acquire); FOR_EACH_RANGE (i, 0, numMaps) { totalCap += subMaps_[i].load(std::memory_order_relaxed)->capacity_; } return totalCap; } // spaceRemaining -- // number of new insertions until current submaps are all at max load template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> size_t AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::spaceRemaining() const { size_t spaceRem(0); int const numMaps = numMapsAllocated_.load(std::memory_order_acquire); FOR_EACH_RANGE (i, 0, numMaps) { SubMap* thisMap = subMaps_[i].load(std::memory_order_relaxed); spaceRem += std::max(0, thisMap->maxEntries_ - &thisMap->numEntries_.readFull()); } return spaceRem; } // clear -- Wipes all keys and values from primary map and destroys // all secondary maps. Not thread safe. template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> void AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::clear() { subMaps_[0].load(std::memory_order_relaxed)->clear(); int const numMaps = numMapsAllocated_.load(std::memory_order_relaxed); FOR_EACH_RANGE (i, 1, numMaps) { SubMap* thisMap = subMaps_[i].load(std::memory_order_relaxed); DCHECK(thisMap); SubMap::destroy(thisMap); subMaps_[i].store(nullptr, std::memory_order_relaxed); } numMapsAllocated_.store(1, std::memory_order_relaxed); } // size -- template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> size_t AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::size() const { size_t totalSize(0); int const numMaps = numMapsAllocated_.load(std::memory_order_acquire); FOR_EACH_RANGE (i, 0, numMaps) { totalSize += subMaps_[i].load(std::memory_order_relaxed)->size(); } return totalSize; } // encodeIndex -- Encode the submap index and offset into return. // index_ret must be pre-populated with the submap offset. // // We leave index_ret untouched when referring to the primary map // so it can be as large as possible (31 data bits). Max size of // secondary maps is limited by what can fit in the low 27 bits. // // Returns the following bit-encoded data in index_ret: // if subMap == 0 (primary map) => // bit(s) value // 31 0 // 0-30 submap offset (index_ret input) // // if subMap > 0 (secondary maps) => // bit(s) value // 31 1 // 27-30 which subMap // 0-26 subMap offset (index_ret input) template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> inline uint32_t AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::encodeIndex(uint32_t subMap, uint32_t offset) { DCHECK_EQ(offset & kSecondaryMapBit_, 0); // offset can't be too big if (subMap == 0) { return offset; } // Make sure subMap isn't too big DCHECK_EQ(subMap >> kNumSubMapBits_, 0); // Make sure subMap bits of offset are clear DCHECK_EQ(offset & (~kSubMapIndexMask_ | kSecondaryMapBit_), 0); // Set high-order bits to encode which submap this index belongs to return offset | (subMap << kSubMapIndexShift_) | kSecondaryMapBit_; } // Iterator implementation template < typename KeyT, typename ValueT, typename HashFcn, typename EqualFcn, typename Allocator, typename ProbeFcn, typename KeyConvertFcn> template struct AtomicHashMap< KeyT, ValueT, HashFcn, EqualFcn, Allocator, ProbeFcn, KeyConvertFcn>::ahm_iterator : boost::iterator_facade< ahm_iterator, IterVal, boost::forward_traversal_tag> { explicit ahm_iterator() : ahm_(nullptr) {} // Conversion ctor for interoperability between const_iterator and // iterator. The enable_if<> magic keeps us well-behaved for // is_convertible<> (v. the iterator_facade documentation). template ahm_iterator( const ahm_iterator& o, typename std::enable_if< std::is_convertible::value>::type* = nullptr) : ahm_(o.ahm_), subMap_(o.subMap_), subIt_(o.subIt_) {} /* * Returns the unique index that can be used for access directly * into the data storage. */ uint32_t getIndex() const { CHECK(!isEnd()); return ahm_->encodeIndex(subMap_, subIt_.getIndex()); } private: friend class AtomicHashMap; explicit ahm_iterator(ContT* ahm, uint32_t subMap, const SubIt& subIt) : ahm_(ahm), subMap_(subMap), subIt_(subIt) {} friend class boost::iterator_core_access; void increment() { CHECK(!isEnd()); ++subIt_; checkAdvanceToNextSubmap(); } bool equal(const ahm_iterator& other) const { if (ahm_ != other.ahm_) { return false; } if (isEnd() || other.isEnd()) { return isEnd() == other.isEnd(); } return subMap_ == other.subMap_ && subIt_ == other.subIt_; } IterVal& dereference() const { return *subIt_; } bool isEnd() const { return ahm_ == nullptr; } void checkAdvanceToNextSubmap() { if (isEnd()) { return; } SubMap* thisMap = ahm_->subMaps_[subMap_].load(std::memory_order_relaxed); while (subIt_ == thisMap->end()) { // This sub iterator is done, advance to next one if (subMap_ + 1 < ahm_->numMapsAllocated_.load(std::memory_order_acquire)) { ++subMap_; thisMap = ahm_->subMaps_[subMap_].load(std::memory_order_relaxed); subIt_ = thisMap->begin(); } else { ahm_ = nullptr; return; } } } private: ContT* ahm_; uint32_t subMap_; SubIt subIt_; }; // ahm_iterator } // namespace folly