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475 lines
17 KiB
C++
475 lines
17 KiB
C++
/*
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* Copyright 2016 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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/*
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* AtomicHashMap --
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*
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* A high-performance concurrent hash map with int32 or int64 keys. Supports
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* insert, find(key), findAt(index), erase(key), size, and more. Memory cannot
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* be freed or reclaimed by erase. Can grow to a maximum of about 18 times the
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* initial capacity, but performance degrades linearly with growth. Can also be
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* used as an object store with unique 32-bit references directly into the
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* internal storage (retrieved with iterator::getIndex()).
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*
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* Advantages:
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* - High-performance (~2-4x tbb::concurrent_hash_map in heavily
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* multi-threaded environments).
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* - Efficient memory usage if initial capacity is not over estimated
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* (especially for small keys and values).
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* - Good fragmentation properties (only allocates in large slabs which can
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* be reused with clear() and never move).
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* - Can generate unique, long-lived 32-bit references for efficient lookup
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* (see findAt()).
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*
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* Disadvantages:
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* - Keys must be native int32 or int64, or explicitly converted.
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* - Must be able to specify unique empty, locked, and erased keys
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* - Performance degrades linearly as size grows beyond initialization
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* capacity.
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* - Max size limit of ~18x initial size (dependent on max load factor).
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* - Memory is not freed or reclaimed by erase.
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*
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* Usage and Operation Details:
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* Simple performance/memory tradeoff with maxLoadFactor. Higher load factors
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* give better memory utilization but probe lengths increase, reducing
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* performance.
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*
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* Implementation and Performance Details:
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* AHArray is a fixed size contiguous block of value_type cells. When
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* writing a cell, the key is locked while the rest of the record is
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* written. Once done, the cell is unlocked by setting the key. find()
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* is completely wait-free and doesn't require any non-relaxed atomic
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* operations. AHA cannot grow beyond initialization capacity, but is
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* faster because of reduced data indirection.
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*
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* AHMap is a wrapper around AHArray sub-maps that allows growth and provides
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* an interface closer to the STL UnorderedAssociativeContainer concept. These
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* sub-maps are allocated on the fly and are processed in series, so the more
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* there are (from growing past initial capacity), the worse the performance.
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*
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* Insert returns false if there is a key collision and throws if the max size
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* of the map is exceeded.
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*
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* Benchmark performance with 8 simultaneous threads processing 1 million
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* unique <int64, int64> entries on a 4-core, 2.5 GHz machine:
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*
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* Load Factor Mem Efficiency usec/Insert usec/Find
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* 50% 50% 0.19 0.05
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* 85% 85% 0.20 0.06
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* 90% 90% 0.23 0.08
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* 95% 95% 0.27 0.10
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*
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* See folly/tests/AtomicHashMapTest.cpp for more benchmarks.
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*
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* @author Spencer Ahrens <sahrens@fb.com>
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* @author Jordan DeLong <delong.j@fb.com>
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*
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*/
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#pragma once
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#define FOLLY_ATOMICHASHMAP_H_
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#include <boost/iterator/iterator_facade.hpp>
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#include <boost/noncopyable.hpp>
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#include <boost/type_traits/is_convertible.hpp>
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#include <stdexcept>
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#include <functional>
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#include <atomic>
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#include <folly/AtomicHashArray.h>
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#include <folly/Foreach.h>
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#include <folly/Hash.h>
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#include <folly/Likely.h>
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#include <folly/ThreadCachedInt.h>
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namespace folly {
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/*
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* AtomicHashMap provides an interface somewhat similar to the
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* UnorderedAssociativeContainer concept in C++. This does not
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* exactly match this concept (or even the basic Container concept),
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* because of some restrictions imposed by our datastructure.
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*
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* Specific differences (there are quite a few):
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*
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* - Efficiently thread safe for inserts (main point of this stuff),
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* wait-free for lookups.
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*
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* - You can erase from this container, but the cell containing the key will
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* not be free or reclaimed.
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*
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* - You can erase everything by calling clear() (and you must guarantee only
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* one thread can be using the container to do that).
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*
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* - We aren't DefaultConstructible, CopyConstructible, Assignable, or
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* EqualityComparable. (Most of these are probably not something
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* you actually want to do with this anyway.)
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*
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* - We don't support the various bucket functions, rehash(),
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* reserve(), or equal_range(). Also no constructors taking
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* iterators, although this could change.
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*
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* - Several insertion functions, notably operator[], are not
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* implemented. It is a little too easy to misuse these functions
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* with this container, where part of the point is that when an
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* insertion happens for a new key, it will atomically have the
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* desired value.
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*
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* - The map has no templated insert() taking an iterator range, but
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* we do provide an insert(key, value). The latter seems more
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* frequently useful for this container (to avoid sprinkling
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* make_pair everywhere), and providing both can lead to some gross
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* template error messages.
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*
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* - The Allocator must not be stateful (a new instance will be spun up for
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* each allocation), and its allocate() method must take a raw number of
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* bytes.
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*
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* - KeyT must be a 32 bit or 64 bit atomic integer type, and you must
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* define special 'locked' and 'empty' key values in the ctor
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*
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* - We don't take the Hash function object as an instance in the
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* constructor.
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*
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*/
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// Thrown when insertion fails due to running out of space for
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// submaps.
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struct AtomicHashMapFullError : std::runtime_error {
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explicit AtomicHashMapFullError()
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: std::runtime_error("AtomicHashMap is full")
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{}
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};
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template<class KeyT, class ValueT, class HashFcn, class EqualFcn,
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class Allocator, class ProbeFcn, class KeyConvertFcn>
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class AtomicHashMap : boost::noncopyable {
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typedef AtomicHashArray<KeyT, ValueT, HashFcn, EqualFcn,
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Allocator, ProbeFcn, KeyConvertFcn>
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SubMap;
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public:
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typedef KeyT key_type;
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typedef ValueT mapped_type;
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typedef std::pair<const KeyT, ValueT> value_type;
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typedef HashFcn hasher;
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typedef EqualFcn key_equal;
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typedef KeyConvertFcn key_convert;
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typedef value_type* pointer;
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typedef value_type& reference;
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typedef const value_type& const_reference;
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typedef std::ptrdiff_t difference_type;
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typedef std::size_t size_type;
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typedef typename SubMap::Config Config;
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template<class ContT, class IterVal, class SubIt>
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struct ahm_iterator;
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typedef ahm_iterator<const AtomicHashMap,
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const value_type,
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typename SubMap::const_iterator>
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const_iterator;
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typedef ahm_iterator<AtomicHashMap,
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value_type,
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typename SubMap::iterator>
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iterator;
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public:
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const float kGrowthFrac_; // How much to grow when we run out of capacity.
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// The constructor takes a finalSizeEst which is the optimal
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// number of elements to maximize space utilization and performance,
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// and a Config object to specify more advanced options.
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explicit AtomicHashMap(size_t finalSizeEst, const Config& c = Config());
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~AtomicHashMap() {
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const int numMaps = numMapsAllocated_.load(std::memory_order_relaxed);
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FOR_EACH_RANGE (i, 0, numMaps) {
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SubMap* thisMap = subMaps_[i].load(std::memory_order_relaxed);
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DCHECK(thisMap);
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SubMap::destroy(thisMap);
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}
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}
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key_equal key_eq() const { return key_equal(); }
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hasher hash_function() const { return hasher(); }
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/*
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* insert --
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*
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* Returns a pair with iterator to the element at r.first and
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* success. Retrieve the index with ret.first.getIndex().
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*
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* Does not overwrite on key collision, but returns an iterator to
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* the existing element (since this could due to a race with
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* another thread, it is often important to check this return
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* value).
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*
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* Allocates new sub maps as the existing ones become full. If
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* all sub maps are full, no element is inserted, and
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* AtomicHashMapFullError is thrown.
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*/
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std::pair<iterator,bool> insert(const value_type& r) {
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return emplace(r.first, r.second);
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}
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std::pair<iterator,bool> insert(key_type k, const mapped_type& v) {
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return emplace(k, v);
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}
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std::pair<iterator,bool> insert(value_type&& r) {
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return emplace(r.first, std::move(r.second));
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}
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std::pair<iterator,bool> insert(key_type k, mapped_type&& v) {
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return emplace(k, std::move(v));
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}
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/*
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* emplace --
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*
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* Same contract as insert(), but performs in-place construction
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* of the value type using the specified arguments.
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*
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* Also, like find(), this method optionally allows 'key_in' to have a type
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* different from that stored in the table; see find(). If and only if no
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* equal key is already present, this method converts 'key_in' to a key of
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* type KeyT using the provided LookupKeyToKeyFcn.
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*/
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template <typename LookupKeyT = key_type,
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typename LookupHashFcn = hasher,
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typename LookupEqualFcn = key_equal,
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typename LookupKeyToKeyFcn = key_convert,
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typename... ArgTs>
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std::pair<iterator,bool> emplace(LookupKeyT k, ArgTs&&... vCtorArg);
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/*
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* find --
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*
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* Returns the iterator to the element if found, otherwise end().
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*
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* As an optional feature, the type of the key to look up (LookupKeyT) is
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* allowed to be different from the type of keys actually stored (KeyT).
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*
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* This enables use cases where materializing the key is costly and usually
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* redudant, e.g., canonicalizing/interning a set of strings and being able
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* to look up by StringPiece. To use this feature, LookupHashFcn must take
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* a LookupKeyT, and LookupEqualFcn must take KeyT and LookupKeyT as first
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* and second parameter, respectively.
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*
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* See folly/test/ArrayHashMapTest.cpp for sample usage.
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*/
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template <typename LookupKeyT = key_type,
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typename LookupHashFcn = hasher,
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typename LookupEqualFcn = key_equal>
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iterator find(LookupKeyT k);
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template <typename LookupKeyT = key_type,
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typename LookupHashFcn = hasher,
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typename LookupEqualFcn = key_equal>
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const_iterator find(LookupKeyT k) const;
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/*
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* erase --
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*
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* Erases key k from the map
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*
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* Returns 1 iff the key is found and erased, and 0 otherwise.
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*/
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size_type erase(key_type k);
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/*
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* clear --
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*
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* Wipes all keys and values from primary map and destroys all secondary
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* maps. Primary map remains allocated and thus the memory can be reused
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* in place. Not thread safe.
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*
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*/
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void clear();
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/*
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* size --
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*
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* Returns the exact size of the map. Note this is not as cheap as typical
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* size() implementations because, for each AtomicHashArray in this AHM, we
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* need to grab a lock and accumulate the values from all the thread local
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* counters. See folly/ThreadCachedInt.h for more details.
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*/
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size_t size() const;
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bool empty() const { return size() == 0; }
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size_type count(key_type k) const {
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return find(k) == end() ? 0 : 1;
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}
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/*
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* findAt --
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*
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* Returns an iterator into the map.
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*
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* idx should only be an unmodified value returned by calling getIndex() on
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* a valid iterator returned by find() or insert(). If idx is invalid you
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* have a bug and the process aborts.
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*/
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iterator findAt(uint32_t idx) {
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SimpleRetT ret = findAtInternal(idx);
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DCHECK_LT(ret.i, numSubMaps());
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return iterator(this, ret.i,
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subMaps_[ret.i].load(std::memory_order_relaxed)->makeIter(ret.j));
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}
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const_iterator findAt(uint32_t idx) const {
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return const_cast<AtomicHashMap*>(this)->findAt(idx);
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}
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// Total capacity - summation of capacities of all submaps.
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size_t capacity() const;
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// Number of new insertions until current submaps are all at max load factor.
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size_t spaceRemaining() const;
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void setEntryCountThreadCacheSize(int32_t newSize) {
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const int numMaps = numMapsAllocated_.load(std::memory_order_acquire);
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for (int i = 0; i < numMaps; ++i) {
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SubMap* map = subMaps_[i].load(std::memory_order_relaxed);
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map->setEntryCountThreadCacheSize(newSize);
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}
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}
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// Number of sub maps allocated so far to implement this map. The more there
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// are, the worse the performance.
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int numSubMaps() const {
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return numMapsAllocated_.load(std::memory_order_acquire);
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}
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iterator begin() {
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iterator it(this, 0,
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subMaps_[0].load(std::memory_order_relaxed)->begin());
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it.checkAdvanceToNextSubmap();
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return it;
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}
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const_iterator begin() const {
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const_iterator it(this, 0,
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subMaps_[0].load(std::memory_order_relaxed)->begin());
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it.checkAdvanceToNextSubmap();
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return it;
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}
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iterator end() {
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return iterator();
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}
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const_iterator end() const {
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return const_iterator();
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}
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/* Advanced functions for direct access: */
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inline uint32_t recToIdx(const value_type& r, bool mayInsert = true) {
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SimpleRetT ret = mayInsert ?
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insertInternal(r.first, r.second) : findInternal(r.first);
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return encodeIndex(ret.i, ret.j);
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}
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inline uint32_t recToIdx(value_type&& r, bool mayInsert = true) {
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SimpleRetT ret = mayInsert ?
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insertInternal(r.first, std::move(r.second)) : findInternal(r.first);
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return encodeIndex(ret.i, ret.j);
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}
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inline uint32_t recToIdx(key_type k, const mapped_type& v,
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bool mayInsert = true) {
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SimpleRetT ret = mayInsert ? insertInternal(k, v) : findInternal(k);
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return encodeIndex(ret.i, ret.j);
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}
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inline uint32_t recToIdx(key_type k, mapped_type&& v, bool mayInsert = true) {
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SimpleRetT ret = mayInsert ?
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insertInternal(k, std::move(v)) : findInternal(k);
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return encodeIndex(ret.i, ret.j);
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}
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inline uint32_t keyToIdx(const KeyT k, bool mayInsert = false) {
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return recToIdx(value_type(k), mayInsert);
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}
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inline const value_type& idxToRec(uint32_t idx) const {
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SimpleRetT ret = findAtInternal(idx);
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return subMaps_[ret.i].load(std::memory_order_relaxed)->idxToRec(ret.j);
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}
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/* Private data and helper functions... */
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private:
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// This limits primary submap size to 2^31 ~= 2 billion, secondary submap
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// size to 2^(32 - kNumSubMapBits_ - 1) = 2^27 ~= 130 million, and num subMaps
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// to 2^kNumSubMapBits_ = 16.
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static const uint32_t kNumSubMapBits_ = 4;
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static const uint32_t kSecondaryMapBit_ = 1u << 31; // Highest bit
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static const uint32_t kSubMapIndexShift_ = 32 - kNumSubMapBits_ - 1;
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static const uint32_t kSubMapIndexMask_ = (1 << kSubMapIndexShift_) - 1;
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static const uint32_t kNumSubMaps_ = 1 << kNumSubMapBits_;
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static const uintptr_t kLockedPtr_ = 0x88ULL << 48; // invalid pointer
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struct SimpleRetT { uint32_t i; size_t j; bool success;
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SimpleRetT(uint32_t ii, size_t jj, bool s) : i(ii), j(jj), success(s) {}
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SimpleRetT() = default;
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};
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template <typename LookupKeyT = key_type,
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typename LookupHashFcn = hasher,
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typename LookupEqualFcn = key_equal,
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typename LookupKeyToKeyFcn = key_convert,
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typename... ArgTs>
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SimpleRetT insertInternal(LookupKeyT key, ArgTs&&... value);
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template <typename LookupKeyT = key_type,
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typename LookupHashFcn = hasher,
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typename LookupEqualFcn = key_equal>
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SimpleRetT findInternal(const LookupKeyT k) const;
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SimpleRetT findAtInternal(uint32_t idx) const;
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std::atomic<SubMap*> subMaps_[kNumSubMaps_];
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std::atomic<uint32_t> numMapsAllocated_;
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inline bool tryLockMap(int idx) {
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SubMap* val = nullptr;
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return subMaps_[idx].compare_exchange_strong(val, (SubMap*)kLockedPtr_,
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std::memory_order_acquire);
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}
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static inline uint32_t encodeIndex(uint32_t subMap, uint32_t subMapIdx);
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}; // AtomicHashMap
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template <class KeyT,
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class ValueT,
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class HashFcn = std::hash<KeyT>,
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class EqualFcn = std::equal_to<KeyT>,
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class Allocator = std::allocator<char>>
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using QuadraticProbingAtomicHashMap =
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AtomicHashMap<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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AtomicHashArrayQuadraticProbeFcn>;
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} // namespace folly
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#include <folly/AtomicHashMap-inl.h>
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