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https://github.com/ecency/ecency-mobile.git
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544 lines
16 KiB
C++
544 lines
16 KiB
C++
/*
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* Copyright 2012-present Facebook, Inc.
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*
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* Licensed under the Apache License, Version 2.0 (the "License");
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* you may not use this file except in compliance with the License.
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* You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing, software
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* distributed under the License is distributed on an "AS IS" BASIS,
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* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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* See the License for the specific language governing permissions and
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* limitations under the License.
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*/
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#ifndef FOLLY_ATOMICHASHARRAY_H_
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#error "This should only be included by AtomicHashArray.h"
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#endif
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#include <type_traits>
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#include <folly/detail/AtomicHashUtils.h>
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#include <folly/lang/Bits.h>
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namespace folly {
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// AtomicHashArray private constructor --
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template <
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class KeyT,
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class ValueT,
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class HashFcn,
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class EqualFcn,
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class Allocator,
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class ProbeFcn,
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class KeyConvertFcn>
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AtomicHashArray<
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KeyT,
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ValueT,
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HashFcn,
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EqualFcn,
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Allocator,
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ProbeFcn,
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KeyConvertFcn>::
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AtomicHashArray(
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size_t capacity,
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KeyT emptyKey,
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KeyT lockedKey,
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KeyT erasedKey,
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double _maxLoadFactor,
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uint32_t cacheSize)
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: capacity_(capacity),
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maxEntries_(size_t(_maxLoadFactor * capacity_ + 0.5)),
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kEmptyKey_(emptyKey),
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kLockedKey_(lockedKey),
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kErasedKey_(erasedKey),
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kAnchorMask_(nextPowTwo(capacity_) - 1),
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numEntries_(0, cacheSize),
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numPendingEntries_(0, cacheSize),
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isFull_(0),
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numErases_(0) {}
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/*
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* findInternal --
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*
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* Sets ret.second to value found and ret.index to index
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* of key and returns true, or if key does not exist returns false and
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* ret.index is set to capacity_.
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*/
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template <
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class KeyT,
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class ValueT,
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class HashFcn,
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class EqualFcn,
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class Allocator,
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class ProbeFcn,
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class KeyConvertFcn>
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template <class LookupKeyT, class LookupHashFcn, class LookupEqualFcn>
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typename AtomicHashArray<
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KeyT,
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ValueT,
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HashFcn,
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EqualFcn,
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Allocator,
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ProbeFcn,
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KeyConvertFcn>::SimpleRetT
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AtomicHashArray<
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KeyT,
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ValueT,
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HashFcn,
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EqualFcn,
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Allocator,
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ProbeFcn,
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KeyConvertFcn>::findInternal(const LookupKeyT key_in) {
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checkLegalKeyIfKey<LookupKeyT>(key_in);
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for (size_t idx = keyToAnchorIdx<LookupKeyT, LookupHashFcn>(key_in),
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numProbes = 0;
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;
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idx = ProbeFcn()(idx, numProbes, capacity_)) {
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const KeyT key = acquireLoadKey(cells_[idx]);
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if (LIKELY(LookupEqualFcn()(key, key_in))) {
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return SimpleRetT(idx, true);
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}
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if (UNLIKELY(key == kEmptyKey_)) {
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// if we hit an empty element, this key does not exist
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return SimpleRetT(capacity_, false);
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}
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// NOTE: the way we count numProbes must be same in find(), insert(),
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// and erase(). Otherwise it may break probing.
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++numProbes;
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if (UNLIKELY(numProbes >= capacity_)) {
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// probed every cell...fail
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return SimpleRetT(capacity_, false);
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}
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}
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}
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/*
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* insertInternal --
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*
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* Returns false on failure due to key collision or full.
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* Also sets ret.index to the index of the key. If the map is full, sets
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* ret.index = capacity_. Also sets ret.second to cell value, thus if insert
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* successful this will be what we just inserted, if there is a key collision
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* this will be the previously inserted value, and if the map is full it is
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* default.
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*/
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template <
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class KeyT,
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class ValueT,
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class HashFcn,
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class EqualFcn,
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class Allocator,
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class ProbeFcn,
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class KeyConvertFcn>
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template <
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typename LookupKeyT,
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typename LookupHashFcn,
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typename LookupEqualFcn,
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typename LookupKeyToKeyFcn,
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typename... ArgTs>
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typename AtomicHashArray<
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KeyT,
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ValueT,
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HashFcn,
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EqualFcn,
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Allocator,
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ProbeFcn,
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KeyConvertFcn>::SimpleRetT
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AtomicHashArray<
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KeyT,
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ValueT,
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HashFcn,
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EqualFcn,
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Allocator,
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ProbeFcn,
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KeyConvertFcn>::insertInternal(LookupKeyT key_in, ArgTs&&... vCtorArgs) {
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const short NO_NEW_INSERTS = 1;
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const short NO_PENDING_INSERTS = 2;
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checkLegalKeyIfKey<LookupKeyT>(key_in);
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size_t idx = keyToAnchorIdx<LookupKeyT, LookupHashFcn>(key_in);
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size_t numProbes = 0;
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for (;;) {
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DCHECK_LT(idx, capacity_);
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value_type* cell = &cells_[idx];
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if (relaxedLoadKey(*cell) == kEmptyKey_) {
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// NOTE: isFull_ is set based on numEntries_.readFast(), so it's
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// possible to insert more than maxEntries_ entries. However, it's not
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// possible to insert past capacity_.
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++numPendingEntries_;
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if (isFull_.load(std::memory_order_acquire)) {
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--numPendingEntries_;
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// Before deciding whether this insert succeeded, this thread needs to
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// wait until no other thread can add a new entry.
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// Correctness assumes isFull_ is true at this point. If
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// another thread now does ++numPendingEntries_, we expect it
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// to pass the isFull_.load() test above. (It shouldn't insert
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// a new entry.)
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detail::atomic_hash_spin_wait([&] {
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return (isFull_.load(std::memory_order_acquire) !=
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NO_PENDING_INSERTS) &&
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(numPendingEntries_.readFull() != 0);
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});
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isFull_.store(NO_PENDING_INSERTS, std::memory_order_release);
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if (relaxedLoadKey(*cell) == kEmptyKey_) {
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// Don't insert past max load factor
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return SimpleRetT(capacity_, false);
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}
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} else {
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// An unallocated cell. Try once to lock it. If we succeed, insert here.
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// If we fail, fall through to comparison below; maybe the insert that
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// just beat us was for this very key....
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if (tryLockCell(cell)) {
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KeyT key_new;
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// Write the value - done before unlocking
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try {
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key_new = LookupKeyToKeyFcn()(key_in);
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typedef
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typename std::remove_const<LookupKeyT>::type LookupKeyTNoConst;
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constexpr bool kAlreadyChecked =
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std::is_same<KeyT, LookupKeyTNoConst>::value;
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if (!kAlreadyChecked) {
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checkLegalKeyIfKey(key_new);
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}
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DCHECK(relaxedLoadKey(*cell) == kLockedKey_);
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// A const mapped_type is only constant once constructed, so cast
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// away any const for the placement new here.
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using mapped = typename std::remove_const<mapped_type>::type;
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new (const_cast<mapped*>(&cell->second))
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ValueT(std::forward<ArgTs>(vCtorArgs)...);
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unlockCell(cell, key_new); // Sets the new key
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} catch (...) {
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// Transition back to empty key---requires handling
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// locked->empty below.
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unlockCell(cell, kEmptyKey_);
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--numPendingEntries_;
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throw;
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}
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// An erase() can race here and delete right after our insertion
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// Direct comparison rather than EqualFcn ok here
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// (we just inserted it)
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DCHECK(
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relaxedLoadKey(*cell) == key_new ||
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relaxedLoadKey(*cell) == kErasedKey_);
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--numPendingEntries_;
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++numEntries_; // This is a thread cached atomic increment :)
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if (numEntries_.readFast() >= maxEntries_) {
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isFull_.store(NO_NEW_INSERTS, std::memory_order_relaxed);
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}
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return SimpleRetT(idx, true);
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}
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--numPendingEntries_;
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}
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}
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DCHECK(relaxedLoadKey(*cell) != kEmptyKey_);
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if (kLockedKey_ == acquireLoadKey(*cell)) {
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detail::atomic_hash_spin_wait(
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[&] { return kLockedKey_ == acquireLoadKey(*cell); });
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}
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const KeyT thisKey = acquireLoadKey(*cell);
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if (LookupEqualFcn()(thisKey, key_in)) {
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// Found an existing entry for our key, but we don't overwrite the
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// previous value.
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return SimpleRetT(idx, false);
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} else if (thisKey == kEmptyKey_ || thisKey == kLockedKey_) {
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// We need to try again (i.e., don't increment numProbes or
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// advance idx): this case can happen if the constructor for
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// ValueT threw for this very cell (the rethrow block above).
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continue;
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}
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// NOTE: the way we count numProbes must be same in find(),
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// insert(), and erase(). Otherwise it may break probing.
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++numProbes;
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if (UNLIKELY(numProbes >= capacity_)) {
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// probed every cell...fail
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return SimpleRetT(capacity_, false);
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}
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idx = ProbeFcn()(idx, numProbes, capacity_);
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}
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}
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/*
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* erase --
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*
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* This will attempt to erase the given key key_in if the key is found. It
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* returns 1 iff the key was located and marked as erased, and 0 otherwise.
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*
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* Memory is not freed or reclaimed by erase, i.e. the cell containing the
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* erased key will never be reused. If there's an associated value, we won't
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* touch it either.
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*/
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template <
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class KeyT,
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class ValueT,
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class HashFcn,
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class EqualFcn,
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class Allocator,
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class ProbeFcn,
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class KeyConvertFcn>
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size_t AtomicHashArray<
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KeyT,
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ValueT,
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HashFcn,
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EqualFcn,
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Allocator,
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ProbeFcn,
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KeyConvertFcn>::erase(KeyT key_in) {
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CHECK_NE(key_in, kEmptyKey_);
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CHECK_NE(key_in, kLockedKey_);
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CHECK_NE(key_in, kErasedKey_);
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for (size_t idx = keyToAnchorIdx(key_in), numProbes = 0;;
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idx = ProbeFcn()(idx, numProbes, capacity_)) {
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DCHECK_LT(idx, capacity_);
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value_type* cell = &cells_[idx];
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KeyT currentKey = acquireLoadKey(*cell);
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if (currentKey == kEmptyKey_ || currentKey == kLockedKey_) {
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// If we hit an empty (or locked) element, this key does not exist. This
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// is similar to how it's handled in find().
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return 0;
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}
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if (EqualFcn()(currentKey, key_in)) {
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// Found an existing entry for our key, attempt to mark it erased.
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// Some other thread may have erased our key, but this is ok.
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KeyT expect = currentKey;
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if (cellKeyPtr(*cell)->compare_exchange_strong(expect, kErasedKey_)) {
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numErases_.fetch_add(1, std::memory_order_relaxed);
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// Even if there's a value in the cell, we won't delete (or even
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// default construct) it because some other thread may be accessing it.
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// Locking it meanwhile won't work either since another thread may be
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// holding a pointer to it.
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// We found the key and successfully erased it.
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return 1;
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}
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// If another thread succeeds in erasing our key, we'll stop our search.
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return 0;
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}
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// NOTE: the way we count numProbes must be same in find(), insert(),
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// and erase(). Otherwise it may break probing.
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++numProbes;
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if (UNLIKELY(numProbes >= capacity_)) {
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// probed every cell...fail
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return 0;
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}
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}
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}
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template <
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class KeyT,
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class ValueT,
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class HashFcn,
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class EqualFcn,
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class Allocator,
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class ProbeFcn,
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class KeyConvertFcn>
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typename AtomicHashArray<
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KeyT,
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ValueT,
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HashFcn,
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EqualFcn,
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Allocator,
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ProbeFcn,
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KeyConvertFcn>::SmartPtr
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AtomicHashArray<
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KeyT,
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ValueT,
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HashFcn,
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EqualFcn,
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Allocator,
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ProbeFcn,
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KeyConvertFcn>::create(size_t maxSize, const Config& c) {
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CHECK_LE(c.maxLoadFactor, 1.0);
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CHECK_GT(c.maxLoadFactor, 0.0);
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CHECK_NE(c.emptyKey, c.lockedKey);
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size_t capacity = size_t(maxSize / c.maxLoadFactor);
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size_t sz = sizeof(AtomicHashArray) + sizeof(value_type) * capacity;
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auto const mem = Allocator().allocate(sz);
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try {
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new (mem) AtomicHashArray(
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capacity,
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c.emptyKey,
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c.lockedKey,
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c.erasedKey,
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c.maxLoadFactor,
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c.entryCountThreadCacheSize);
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} catch (...) {
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Allocator().deallocate(mem, sz);
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throw;
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}
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SmartPtr map(static_cast<AtomicHashArray*>((void*)mem));
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/*
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* Mark all cells as empty.
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*
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* Note: we're bending the rules a little here accessing the key
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* element in our cells even though the cell object has not been
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* constructed, and casting them to atomic objects (see cellKeyPtr).
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* (Also, in fact we never actually invoke the value_type
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* constructor.) This is in order to avoid needing to default
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* construct a bunch of value_type when we first start up: if you
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* have an expensive default constructor for the value type this can
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* noticeably speed construction time for an AHA.
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*/
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FOR_EACH_RANGE (i, 0, map->capacity_) {
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cellKeyPtr(map->cells_[i])
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->store(map->kEmptyKey_, std::memory_order_relaxed);
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}
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return map;
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}
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template <
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class KeyT,
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class ValueT,
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class HashFcn,
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class EqualFcn,
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class Allocator,
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class ProbeFcn,
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class KeyConvertFcn>
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void AtomicHashArray<
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KeyT,
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ValueT,
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HashFcn,
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EqualFcn,
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Allocator,
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ProbeFcn,
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KeyConvertFcn>::destroy(AtomicHashArray* p) {
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assert(p);
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size_t sz = sizeof(AtomicHashArray) + sizeof(value_type) * p->capacity_;
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FOR_EACH_RANGE (i, 0, p->capacity_) {
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if (p->cells_[i].first != p->kEmptyKey_) {
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p->cells_[i].~value_type();
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}
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}
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p->~AtomicHashArray();
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Allocator().deallocate((char*)p, sz);
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}
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// clear -- clears all keys and values in the map and resets all counters
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template <
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class KeyT,
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class ValueT,
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class HashFcn,
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class EqualFcn,
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class Allocator,
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class ProbeFcn,
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class KeyConvertFcn>
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void AtomicHashArray<
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KeyT,
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ValueT,
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HashFcn,
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EqualFcn,
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Allocator,
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ProbeFcn,
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KeyConvertFcn>::clear() {
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FOR_EACH_RANGE (i, 0, capacity_) {
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if (cells_[i].first != kEmptyKey_) {
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cells_[i].~value_type();
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*const_cast<KeyT*>(&cells_[i].first) = kEmptyKey_;
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}
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CHECK(cells_[i].first == kEmptyKey_);
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}
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numEntries_.set(0);
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numPendingEntries_.set(0);
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isFull_.store(0, std::memory_order_relaxed);
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numErases_.store(0, std::memory_order_relaxed);
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}
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// Iterator implementation
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template <
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class KeyT,
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class ValueT,
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class HashFcn,
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class EqualFcn,
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class Allocator,
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class ProbeFcn,
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class KeyConvertFcn>
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template <class ContT, class IterVal>
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struct AtomicHashArray<
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KeyT,
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ValueT,
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HashFcn,
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EqualFcn,
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Allocator,
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ProbeFcn,
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KeyConvertFcn>::aha_iterator
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: boost::iterator_facade<
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aha_iterator<ContT, IterVal>,
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IterVal,
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boost::forward_traversal_tag> {
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explicit aha_iterator() : aha_(nullptr) {}
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// Conversion ctor for interoperability between const_iterator and
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// iterator. The enable_if<> magic keeps us well-behaved for
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// is_convertible<> (v. the iterator_facade documentation).
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template <class OtherContT, class OtherVal>
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aha_iterator(
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const aha_iterator<OtherContT, OtherVal>& o,
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typename std::enable_if<
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std::is_convertible<OtherVal*, IterVal*>::value>::type* = nullptr)
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: aha_(o.aha_), offset_(o.offset_) {}
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explicit aha_iterator(ContT* array, size_t offset)
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: aha_(array), offset_(offset) {}
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// Returns unique index that can be used with findAt().
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// WARNING: The following function will fail silently for hashtable
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// with capacity > 2^32
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uint32_t getIndex() const {
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return offset_;
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}
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void advancePastEmpty() {
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while (offset_ < aha_->capacity_ && !isValid()) {
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++offset_;
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}
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}
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private:
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friend class AtomicHashArray;
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friend class boost::iterator_core_access;
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void increment() {
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++offset_;
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advancePastEmpty();
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}
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bool equal(const aha_iterator& o) const {
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return aha_ == o.aha_ && offset_ == o.offset_;
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}
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IterVal& dereference() const {
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return aha_->cells_[offset_];
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}
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bool isValid() const {
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KeyT key = acquireLoadKey(aha_->cells_[offset_]);
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return key != aha_->kEmptyKey_ && key != aha_->kLockedKey_ &&
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key != aha_->kErasedKey_;
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}
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private:
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ContT* aha_;
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size_t offset_;
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}; // aha_iterator
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} // namespace folly
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