/* * Copyright (c) Facebook, Inc. and its affiliates. * * 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. */ #pragma once /** * F14NodeMap, F14ValueMap, and F14VectorMap * * F14FastMap conditionally works like F14ValueMap or F14VectorMap * * See F14.md * * @author Nathan Bronson * @author Xiao Shi */ #include #include #include #include #include #include #include #include #include #include #include #include #if FOLLY_F14_VECTOR_INTRINSICS_AVAILABLE //////// Common case for supported platforms namespace folly { namespace f14 { namespace detail { template class F14BasicMap { template using EnableHeterogeneousFind = std::enable_if_t< EligibleForHeterogeneousFind< typename Policy::Key, typename Policy::Hasher, typename Policy::KeyEqual, K>::value, T>; template using EnableHeterogeneousInsert = std::enable_if_t< EligibleForHeterogeneousInsert< typename Policy::Key, typename Policy::Hasher, typename Policy::KeyEqual, K>::value, T>; template using EnableHeterogeneousErase = std::enable_if_t< EligibleForHeterogeneousFind< typename Policy::Value, typename Policy::Hasher, typename Policy::KeyEqual, K>::value && !std::is_same>::value && !std::is_same>::value, T>; public: //// PUBLIC - Member types using key_type = typename Policy::Key; using mapped_type = typename Policy::Mapped; using value_type = typename Policy::Value; using size_type = std::size_t; using difference_type = std::ptrdiff_t; using hasher = typename Policy::Hasher; using key_equal = typename Policy::KeyEqual; using allocator_type = typename Policy::Alloc; using reference = value_type&; using const_reference = value_type const&; using pointer = typename Policy::AllocTraits::pointer; using const_pointer = typename Policy::AllocTraits::const_pointer; using iterator = typename Policy::Iter; using const_iterator = typename Policy::ConstIter; private: using ItemIter = typename Policy::ItemIter; public: //// PUBLIC - Member functions F14BasicMap() noexcept(Policy::kDefaultConstructIsNoexcept) : F14BasicMap(0) {} explicit F14BasicMap( std::size_t initialCapacity, hasher const& hash = hasher{}, key_equal const& eq = key_equal{}, allocator_type const& alloc = allocator_type{}) : table_{initialCapacity, hash, eq, alloc} {} explicit F14BasicMap(std::size_t initialCapacity, allocator_type const& alloc) : F14BasicMap(initialCapacity, hasher{}, key_equal{}, alloc) {} explicit F14BasicMap( std::size_t initialCapacity, hasher const& hash, allocator_type const& alloc) : F14BasicMap(initialCapacity, hash, key_equal{}, alloc) {} explicit F14BasicMap(allocator_type const& alloc) : F14BasicMap(0, hasher{}, key_equal{}, alloc) {} template F14BasicMap( InputIt first, InputIt last, std::size_t initialCapacity = 0, hasher const& hash = hasher{}, key_equal const& eq = key_equal{}, allocator_type const& alloc = allocator_type{}) : table_{initialCapacity, hash, eq, alloc} { initialInsert(first, last, initialCapacity); } template F14BasicMap( InputIt first, InputIt last, std::size_t initialCapacity, allocator_type const& alloc) : table_{initialCapacity, hasher{}, key_equal{}, alloc} { initialInsert(first, last, initialCapacity); } template F14BasicMap( InputIt first, InputIt last, std::size_t initialCapacity, hasher const& hash, allocator_type const& alloc) : table_{initialCapacity, hash, key_equal{}, alloc} { initialInsert(first, last, initialCapacity); } F14BasicMap(F14BasicMap const& rhs) = default; F14BasicMap(F14BasicMap const& rhs, allocator_type const& alloc) : table_{rhs.table_, alloc} {} F14BasicMap(F14BasicMap&& rhs) = default; F14BasicMap(F14BasicMap&& rhs, allocator_type const& alloc) noexcept( Policy::kAllocIsAlwaysEqual) : table_{std::move(rhs.table_), alloc} {} F14BasicMap( std::initializer_list init, std::size_t initialCapacity = 0, hasher const& hash = hasher{}, key_equal const& eq = key_equal{}, allocator_type const& alloc = allocator_type{}) : table_{initialCapacity, hash, eq, alloc} { initialInsert(init.begin(), init.end(), initialCapacity); } F14BasicMap( std::initializer_list init, std::size_t initialCapacity, allocator_type const& alloc) : table_{initialCapacity, hasher{}, key_equal{}, alloc} { initialInsert(init.begin(), init.end(), initialCapacity); } F14BasicMap( std::initializer_list init, std::size_t initialCapacity, hasher const& hash, allocator_type const& alloc) : table_{initialCapacity, hash, key_equal{}, alloc} { initialInsert(init.begin(), init.end(), initialCapacity); } F14BasicMap& operator=(F14BasicMap const&) = default; F14BasicMap& operator=(F14BasicMap&&) = default; F14BasicMap& operator=(std::initializer_list ilist) { clear(); bulkInsert(ilist.begin(), ilist.end(), false); return *this; } allocator_type get_allocator() const noexcept { return table_.alloc(); } //// PUBLIC - Iterators iterator begin() noexcept { return table_.makeIter(table_.begin()); } const_iterator begin() const noexcept { return cbegin(); } const_iterator cbegin() const noexcept { return table_.makeConstIter(table_.begin()); } iterator end() noexcept { return table_.makeIter(table_.end()); } const_iterator end() const noexcept { return cend(); } const_iterator cend() const noexcept { return table_.makeConstIter(table_.end()); } //// PUBLIC - Capacity bool empty() const noexcept { return table_.empty(); } std::size_t size() const noexcept { return table_.size(); } std::size_t max_size() const noexcept { return table_.max_size(); } //// PUBLIC - Modifiers void clear() noexcept { table_.clear(); } std::pair insert(value_type const& value) { return emplace(value); } template std::enable_if_t< std::is_constructible::value, std::pair> insert(P&& value) { return emplace(std::forward

(value)); } // TODO(T31574848): Work around libstdc++ versions (e.g., GCC < 6) with no // implementation of N4387 ("perfect initialization" for pairs and tuples). template std::enable_if_t< std::is_constructible::value && std::is_constructible::value, std::pair> insert(std::pair const& value) { return emplace(value); } // TODO(T31574848) template std::enable_if_t< std::is_constructible::value && std::is_constructible::value, std::pair> insert(std::pair&& value) { return emplace(std::move(value)); } std::pair insert(value_type&& value) { return emplace(std::move(value)); } // std::unordered_map's hinted insertion API is misleading. No // implementation I've seen actually uses the hint. Code restructuring // by the caller to use the hinted API is at best unnecessary, and at // worst a pessimization. It is used, however, so we provide it. iterator insert(const_iterator /*hint*/, value_type const& value) { return insert(value).first; } template std::enable_if_t::value, iterator> insert(const_iterator /*hint*/, P&& value) { return insert(std::forward

(value)).first; } iterator insert(const_iterator /*hint*/, value_type&& value) { return insert(std::move(value)).first; } template iterator emplace_hint(const_iterator /*hint*/, Args&&... args) { return emplace(std::forward(args)...).first; } private: template FOLLY_ALWAYS_INLINE void bulkInsert(InputIt first, InputIt last, bool autoReserve) { if (autoReserve) { auto n = std::distance(first, last); if (n == 0) { return; } table_.reserveForInsert(n); } while (first != last) { insert(*first); ++first; } } template void initialInsert(InputIt first, InputIt last, std::size_t initialCapacity) { FOLLY_SAFE_DCHECK(empty() && bucket_count() >= initialCapacity, ""); // It's possible that there are a lot of duplicates in first..last and // so we will oversize ourself. The common case, however, is that // we can avoid a lot of rehashing if we pre-expand. The behavior // is easy to disable at a particular call site by asking for an // initialCapacity of 1. bool autoReserve = std::is_same< typename std::iterator_traits::iterator_category, std::random_access_iterator_tag>::value && initialCapacity == 0; bulkInsert(first, last, autoReserve); } public: template void insert(InputIt first, InputIt last) { // Bulk reserve is a heuristic choice, so it can backfire. We restrict // ourself to situations that mimic bulk construction without an // explicit initialCapacity. bool autoReserve = std::is_same< typename std::iterator_traits::iterator_category, std::random_access_iterator_tag>::value && bucket_count() == 0; bulkInsert(first, last, autoReserve); } void insert(std::initializer_list ilist) { insert(ilist.begin(), ilist.end()); } template std::pair insert_or_assign(key_type const& key, M&& obj) { auto rv = try_emplace(key, std::forward(obj)); if (!rv.second) { rv.first->second = std::forward(obj); } return rv; } template std::pair insert_or_assign(key_type&& key, M&& obj) { auto rv = try_emplace(std::move(key), std::forward(obj)); if (!rv.second) { rv.first->second = std::forward(obj); } return rv; } template iterator insert_or_assign(const_iterator /*hint*/, key_type const& key, M&& obj) { return insert_or_assign(key, std::move(obj)).first; } template iterator insert_or_assign(const_iterator /*hint*/, key_type&& key, M&& obj) { return insert_or_assign(std::move(key), std::move(obj)).first; } template EnableHeterogeneousInsert> insert_or_assign( K&& key, M&& obj) { auto rv = try_emplace(std::forward(key), std::forward(obj)); if (!rv.second) { rv.first->second = std::forward(obj); } return rv; } private: template using UsableAsKey = EligibleForHeterogeneousFind; public: template std::pair emplace(Args&&... args) { auto rv = folly::detail::callWithExtractedKey( table_.alloc(), [&](auto&&... inner) { return table_.tryEmplaceValue( std::forward(inner)...); }, std::forward(args)...); return std::make_pair(table_.makeIter(rv.first), rv.second); } template std::pair try_emplace(key_type const& key, Args&&... args) { auto rv = table_.tryEmplaceValue( key, std::piecewise_construct, std::forward_as_tuple(key), std::forward_as_tuple(std::forward(args)...)); return std::make_pair(table_.makeIter(rv.first), rv.second); } template std::pair try_emplace(key_type&& key, Args&&... args) { auto rv = table_.tryEmplaceValue( key, std::piecewise_construct, std::forward_as_tuple(std::move(key)), std::forward_as_tuple(std::forward(args)...)); return std::make_pair(table_.makeIter(rv.first), rv.second); } template iterator try_emplace(const_iterator /*hint*/, key_type const& key, Args&&... args) { auto rv = table_.tryEmplaceValue( key, std::piecewise_construct, std::forward_as_tuple(key), std::forward_as_tuple(std::forward(args)...)); return table_.makeIter(rv.first); } template iterator try_emplace(const_iterator /*hint*/, key_type&& key, Args&&... args) { auto rv = table_.tryEmplaceValue( key, std::piecewise_construct, std::forward_as_tuple(std::move(key)), std::forward_as_tuple(std::forward(args)...)); return table_.makeIter(rv.first); } template EnableHeterogeneousInsert> try_emplace( K&& key, Args&&... args) { auto rv = table_.tryEmplaceValue( key, std::piecewise_construct, std::forward_as_tuple(std::forward(key)), std::forward_as_tuple(std::forward(args)...)); return std::make_pair(table_.makeIter(rv.first), rv.second); } FOLLY_ALWAYS_INLINE iterator erase(const_iterator pos) { return eraseInto(pos, [](key_type&&, mapped_type&&) {}); } // This form avoids ambiguity when key_type has a templated constructor // that accepts const_iterator FOLLY_ALWAYS_INLINE iterator erase(iterator pos) { return eraseInto(pos, [](key_type&&, mapped_type&&) {}); } iterator erase(const_iterator first, const_iterator last) { return eraseInto(first, last, [](key_type&&, mapped_type&&) {}); } size_type erase(key_type const& key) { return eraseInto(key, [](key_type&&, mapped_type&&) {}); } template EnableHeterogeneousErase erase(K const& key) { return eraseInto(key, [](key_type&&, mapped_type&&) {}); } protected: template FOLLY_ALWAYS_INLINE void tableEraseIterInto( ItemIter pos, BeforeDestroy&& beforeDestroy) { table_.eraseIterInto(pos, [&](value_type&& v) { auto p = Policy::moveValue(v); beforeDestroy(std::move(p.first), std::move(p.second)); }); } template FOLLY_ALWAYS_INLINE std::size_t tableEraseKeyInto( K const& key, BeforeDestroy&& beforeDestroy) { return table_.eraseKeyInto(key, [&](value_type&& v) { auto p = Policy::moveValue(v); beforeDestroy(std::move(p.first), std::move(p.second)); }); } public: // eraseInto contains the same overloads as erase but provides // an additional callback argument which is called with an rvalue // reference (not const) to the key and an rvalue reference to the // mapped value directly before it is destroyed. This can be used // to extract an entry out of a F14Map while avoiding a copy. template FOLLY_ALWAYS_INLINE iterator eraseInto(const_iterator pos, BeforeDestroy&& beforeDestroy) { // If we are inlined then gcc and clang can optimize away all of the // work of itemPos.advance() if our return value is discarded. auto itemPos = table_.unwrapIter(pos); tableEraseIterInto(itemPos, beforeDestroy); itemPos.advanceLikelyDead(); return table_.makeIter(itemPos); } // This form avoids ambiguity when key_type has a templated constructor // that accepts const_iterator template FOLLY_ALWAYS_INLINE iterator eraseInto(iterator pos, BeforeDestroy&& beforeDestroy) { const_iterator cpos{pos}; return eraseInto(cpos, beforeDestroy); } template iterator eraseInto( const_iterator first, const_iterator last, BeforeDestroy&& beforeDestroy) { auto itemFirst = table_.unwrapIter(first); auto itemLast = table_.unwrapIter(last); while (itemFirst != itemLast) { tableEraseIterInto(itemFirst, beforeDestroy); itemFirst.advance(); } return table_.makeIter(itemFirst); } template size_type eraseInto(key_type const& key, BeforeDestroy&& beforeDestroy) { return tableEraseKeyInto(key, beforeDestroy); } template EnableHeterogeneousErase eraseInto( K const& key, BeforeDestroy&& beforeDestroy) { return tableEraseKeyInto(key, beforeDestroy); } //// PUBLIC - Lookup FOLLY_ALWAYS_INLINE mapped_type& at(key_type const& key) { return at(*this, key); } FOLLY_ALWAYS_INLINE mapped_type const& at(key_type const& key) const { return at(*this, key); } template EnableHeterogeneousFind at(K const& key) { return at(*this, key); } template EnableHeterogeneousFind at(K const& key) const { return at(*this, key); } mapped_type& operator[](key_type const& key) { return try_emplace(key).first->second; } mapped_type& operator[](key_type&& key) { return try_emplace(std::move(key)).first->second; } template EnableHeterogeneousInsert operator[](K&& key) { return try_emplace(std::forward(key)).first->second; } FOLLY_ALWAYS_INLINE size_type count(key_type const& key) const { return contains(key) ? 1 : 0; } template FOLLY_ALWAYS_INLINE EnableHeterogeneousFind count( K const& key) const { return contains(key) ? 1 : 0; } // prehash(key) does the work of evaluating hash_function()(key) // (including additional bit-mixing for non-avalanching hash functions), // wraps the result of that work in a token for later reuse, and // begins prefetching the first steps of looking for key into the // local CPU cache. // // The returned token may be used at any time, may be used more than // once, and may be used in other F14 sets and maps. Tokens are // transferrable between any F14 containers (maps and sets) with the // same key_type and equal hash_function()s. // // Hash tokens are not hints -- it is a bug to call any method on this // class with a token t and key k where t isn't the result of a call // to prehash(k2) with k2 == k. F14HashToken prehash(key_type const& key) const { return table_.prehash(key); } template EnableHeterogeneousFind prehash(K const& key) const { return table_.prehash(key); } FOLLY_ALWAYS_INLINE iterator find(key_type const& key) { return table_.makeIter(table_.find(key)); } FOLLY_ALWAYS_INLINE const_iterator find(key_type const& key) const { return table_.makeConstIter(table_.find(key)); } FOLLY_ALWAYS_INLINE iterator find(F14HashToken const& token, key_type const& key) { return table_.makeIter(table_.find(token, key)); } FOLLY_ALWAYS_INLINE const_iterator find(F14HashToken const& token, key_type const& key) const { return table_.makeConstIter(table_.find(token, key)); } template FOLLY_ALWAYS_INLINE EnableHeterogeneousFind find(K const& key) { return table_.makeIter(table_.find(key)); } template FOLLY_ALWAYS_INLINE EnableHeterogeneousFind find( K const& key) const { return table_.makeConstIter(table_.find(key)); } template FOLLY_ALWAYS_INLINE EnableHeterogeneousFind find( F14HashToken const& token, K const& key) { return table_.makeIter(table_.find(token, key)); } template FOLLY_ALWAYS_INLINE EnableHeterogeneousFind find( F14HashToken const& token, K const& key) const { return table_.makeConstIter(table_.find(token, key)); } FOLLY_ALWAYS_INLINE bool contains(key_type const& key) const { return !table_.find(key).atEnd(); } template FOLLY_ALWAYS_INLINE EnableHeterogeneousFind contains( K const& key) const { return !table_.find(key).atEnd(); } FOLLY_ALWAYS_INLINE bool contains( F14HashToken const& token, key_type const& key) const { return !table_.find(token, key).atEnd(); } template FOLLY_ALWAYS_INLINE EnableHeterogeneousFind contains( F14HashToken const& token, K const& key) const { return !table_.find(token, key).atEnd(); } std::pair equal_range(key_type const& key) { return equal_range(*this, key); } std::pair equal_range( key_type const& key) const { return equal_range(*this, key); } template EnableHeterogeneousFind> equal_range( K const& key) { return equal_range(*this, key); } template EnableHeterogeneousFind> equal_range(K const& key) const { return equal_range(*this, key); } //// PUBLIC - Bucket interface std::size_t bucket_count() const noexcept { return table_.bucket_count(); } std::size_t max_bucket_count() const noexcept { return table_.max_bucket_count(); } //// PUBLIC - Hash policy float load_factor() const noexcept { return table_.load_factor(); } float max_load_factor() const noexcept { return table_.max_load_factor(); } void max_load_factor(float v) { table_.max_load_factor(v); } void rehash(std::size_t bucketCapacity) { // The standard's rehash() requires understanding the max load factor, // which is easy to get wrong. Since we don't actually allow adjustment // of max_load_factor there is no difference. reserve(bucketCapacity); } void reserve(std::size_t capacity) { table_.reserve(capacity); } //// PUBLIC - Observers hasher hash_function() const { return table_.hasher(); } key_equal key_eq() const { return table_.keyEqual(); } //// PUBLIC - F14 Extensions // containsEqualValue returns true iff there is an element in the map // that compares equal to value using operator==. It is undefined // behavior to call this function if operator== on key_type can ever // return true when the same keys passed to key_eq() would return false // (the opposite is allowed). bool containsEqualValue(value_type const& value) const { auto it = table_.findMatching( value.first, [&](auto& key) { return value.first == key; }); return !it.atEnd() && value.second == table_.valueAtItem(it.citem()).second; } // Get memory footprint, not including sizeof(*this). std::size_t getAllocatedMemorySize() const { return table_.getAllocatedMemorySize(); } // Enumerates classes of allocated memory blocks currently owned // by this table, calling visitor(allocationSize, allocationCount). // This can be used to get a more accurate indication of memory footprint // than getAllocatedMemorySize() if you have some way of computing the // internal fragmentation of the allocator, such as JEMalloc's nallocx. // The visitor might be called twice with the same allocationSize. The // visitor's computation should produce the same result for visitor(8, // 2) as for two calls to visitor(8, 1), for example. The visitor may // be called with a zero allocationCount. template void visitAllocationClasses(V&& visitor) const { return table_.visitAllocationClasses(visitor); } // Calls visitor with two value_type const*, b and e, such that every // entry in the table is included in exactly one of the ranges [b,e). // This can be used to efficiently iterate elements in bulk when crossing // an API boundary that supports contiguous blocks of items. template void visitContiguousRanges(V&& visitor) const; F14TableStats computeStats() const noexcept { return table_.computeStats(); } private: template FOLLY_ALWAYS_INLINE static auto& at(Self& self, K const& key) { auto iter = self.find(key); if (iter == self.end()) { throw_exception("at() did not find key"); } return iter->second; } template static auto equal_range(Self& self, K const& key) { auto first = self.find(key); auto last = first; if (last != self.end()) { ++last; } return std::make_pair(first, last); } protected: F14Table table_; }; } // namespace detail } // namespace f14 template < typename Key, typename Mapped, typename Hasher, typename KeyEqual, typename Alloc> class F14ValueMap : public f14::detail::F14BasicMap> { protected: using Policy = f14::detail::MapPolicyWithDefaults< f14::detail::ValueContainerPolicy, Key, Mapped, Hasher, KeyEqual, Alloc>; private: using Super = f14::detail::F14BasicMap; public: using typename Super::value_type; F14ValueMap() = default; using Super::Super; F14ValueMap& operator=(std::initializer_list ilist) { Super::operator=(ilist); return *this; } void swap(F14ValueMap& rhs) noexcept(Policy::kSwapIsNoexcept) { this->table_.swap(rhs.table_); } template void visitContiguousRanges(V&& visitor) const { this->table_.visitContiguousItemRanges(visitor); } }; template < typename Key, typename Mapped, typename Hasher, typename KeyEqual, typename Alloc> class F14NodeMap : public f14::detail::F14BasicMap> { protected: using Policy = f14::detail::MapPolicyWithDefaults< f14::detail::NodeContainerPolicy, Key, Mapped, Hasher, KeyEqual, Alloc>; private: using Super = f14::detail::F14BasicMap; public: using typename Super::value_type; F14NodeMap() = default; using Super::Super; F14NodeMap& operator=(std::initializer_list ilist) { Super::operator=(ilist); return *this; } void swap(F14NodeMap& rhs) noexcept(Policy::kSwapIsNoexcept) { this->table_.swap(rhs.table_); } template void visitContiguousRanges(V&& visitor) const { this->table_.visitItems([&](typename Policy::Item ptr) { value_type const* b = std::addressof(*ptr); visitor(b, b + 1); }); } // TODO extract and node_handle insert }; namespace f14 { namespace detail { template < typename Key, typename Mapped, typename Hasher, typename KeyEqual, typename Alloc, typename EligibleForPerturbedInsertionOrder> class F14VectorMapImpl : public F14BasicMap> { protected: using Policy = MapPolicyWithDefaults< VectorContainerPolicy, Key, Mapped, Hasher, KeyEqual, Alloc, EligibleForPerturbedInsertionOrder>; private: using Super = F14BasicMap; template using EnableHeterogeneousVectorErase = std::enable_if_t< EligibleForHeterogeneousFind< typename Policy::Value, typename Policy::Hasher, typename Policy::KeyEqual, K>::value && !std::is_same>::value && !std::is_same>::value && !std::is_same>:: value && !std::is_same>:: value, T>; public: using typename Super::const_iterator; using typename Super::iterator; using typename Super::key_type; using typename Super::mapped_type; using typename Super::value_type; F14VectorMapImpl() = default; // inherit constructors using Super::Super; F14VectorMapImpl& operator=(std::initializer_list ilist) { Super::operator=(ilist); return *this; } iterator begin() { return this->table_.linearBegin(this->size()); } const_iterator begin() const { return cbegin(); } const_iterator cbegin() const { return this->table_.linearBegin(this->size()); } iterator end() { return this->table_.linearEnd(); } const_iterator end() const { return cend(); } const_iterator cend() const { return this->table_.linearEnd(); } private: template void eraseUnderlying( typename Policy::ItemIter underlying, BeforeDestroy&& beforeDestroy) { Alloc& a = this->table_.alloc(); auto values = this->table_.values_; // Remove the ptr from the base table and destroy the value. auto index = underlying.item(); // The item still needs to be hashable during this call, so we must destroy // the value _afterwards_. this->tableEraseIterInto(underlying, beforeDestroy); Policy::AllocTraits::destroy(a, std::addressof(values[index])); // move the last element in values_ down and fix up the inbound index auto tailIndex = this->size(); if (tailIndex != index) { auto tail = this->table_.find( VectorContainerIndexSearch{static_cast(tailIndex)}); tail.item() = index; auto p = std::addressof(values[index]); assume(p != nullptr); this->table_.transfer(a, std::addressof(values[tailIndex]), p, 1); } } template std::size_t eraseUnderlyingKey(K const& key, BeforeDestroy&& beforeDestroy) { auto underlying = this->table_.find(key); if (underlying.atEnd()) { return 0; } else { eraseUnderlying(underlying, beforeDestroy); return 1; } } public: FOLLY_ALWAYS_INLINE iterator erase(const_iterator pos) { return eraseInto(pos, [](key_type&&, mapped_type&&) {}); } // This form avoids ambiguity when key_type has a templated constructor // that accepts const_iterator FOLLY_ALWAYS_INLINE iterator erase(iterator pos) { return eraseInto(pos, [](key_type&&, mapped_type&&) {}); } iterator erase(const_iterator first, const_iterator last) { return eraseInto(first, last, [](key_type&&, mapped_type&&) {}); } std::size_t erase(key_type const& key) { return eraseInto(key, [](key_type&&, mapped_type&&) {}); } template EnableHeterogeneousVectorErase erase(K const& key) { return eraseInto(key, [](key_type&&, mapped_type&&) {}); } template FOLLY_ALWAYS_INLINE iterator eraseInto(const_iterator pos, BeforeDestroy&& beforeDestroy) { auto index = this->table_.iterToIndex(pos); auto underlying = this->table_.find(VectorContainerIndexSearch{index}); eraseUnderlying(underlying, beforeDestroy); return index == 0 ? end() : this->table_.indexToIter(index - 1); } // This form avoids ambiguity when key_type has a templated constructor // that accepts const_iterator template FOLLY_ALWAYS_INLINE iterator eraseInto(iterator pos, BeforeDestroy&& beforeDestroy) { const_iterator cpos{pos}; return eraseInto(cpos, beforeDestroy); } template iterator eraseInto( const_iterator first, const_iterator last, BeforeDestroy&& beforeDestroy) { while (first != last) { first = eraseInto(first, beforeDestroy); } auto index = this->table_.iterToIndex(first); return index == 0 ? end() : this->table_.indexToIter(index - 1); } template std::size_t eraseInto(key_type const& key, BeforeDestroy&& beforeDestroy) { return eraseUnderlyingKey(key, beforeDestroy); } template EnableHeterogeneousVectorErase eraseInto( K const& key, BeforeDestroy&& beforeDestroy) { return eraseUnderlyingKey(key, beforeDestroy); } template void visitContiguousRanges(V&& visitor) const { auto n = this->table_.size(); if (n > 0) { value_type const* b = std::addressof(this->table_.values_[0]); visitor(b, b + n); } } }; } // namespace detail } // namespace f14 template < typename Key, typename Mapped, typename Hasher, typename KeyEqual, typename Alloc> class F14VectorMap : public f14::detail::F14VectorMapImpl< Key, Mapped, Hasher, KeyEqual, Alloc, std::false_type> { using Super = f14::detail:: F14VectorMapImpl; public: using typename Super::const_iterator; using typename Super::iterator; using typename Super::value_type; using reverse_iterator = typename Super::Policy::ReverseIter; using const_reverse_iterator = typename Super::Policy::ConstReverseIter; F14VectorMap() = default; // inherit constructors using Super::Super; F14VectorMap& operator=(std::initializer_list ilist) { Super::operator=(ilist); return *this; } void swap(F14VectorMap& rhs) noexcept(Super::Policy::kSwapIsNoexcept) { this->table_.swap(rhs.table_); } // ITERATION ORDER // // Deterministic iteration order for insert-only workloads is part of // F14VectorMap's supported API: iterator is LIFO and reverse_iterator // is FIFO. // // If there have been no calls to erase() then iterator and // const_iterator enumerate entries in the opposite of insertion order. // begin()->first is the key most recently inserted. reverse_iterator // and reverse_const_iterator, therefore, enumerate in LIFO (insertion) // order for insert-only workloads. Deterministic iteration order is // only guaranteed if no keys were removed since the last time the // map was empty. Iteration order is preserved across rehashes and // F14VectorMap copies and moves. // // iterator uses LIFO order so that erasing while iterating with begin() // and end() is safe using the erase(it++) idiom, which is supported // by std::map and std::unordered_map. erase(iter) invalidates iter // and all iterators before iter in the non-reverse iteration order. // Every successful erase invalidates all reverse iterators. // // No erase is provided for reverse_iterator or const_reverse_iterator // to make it harder to shoot yourself in the foot by erasing while // reverse-iterating. You can write that as map.erase(map.iter(riter)) // if you really need it. reverse_iterator rbegin() { return this->table_.values_; } const_reverse_iterator rbegin() const { return crbegin(); } const_reverse_iterator crbegin() const { return this->table_.values_; } reverse_iterator rend() { return this->table_.values_ + this->table_.size(); } const_reverse_iterator rend() const { return crend(); } const_reverse_iterator crend() const { return this->table_.values_ + this->table_.size(); } // explicit conversions between iterator and reverse_iterator iterator iter(reverse_iterator riter) { return this->table_.iter(riter); } const_iterator iter(const_reverse_iterator riter) const { return this->table_.iter(riter); } reverse_iterator riter(iterator it) { return this->table_.riter(it); } const_reverse_iterator riter(const_iterator it) const { return this->table_.riter(it); } }; template Range::const_reverse_iterator> order_preserving_reinsertion_view(const F14VectorMap& c) { return {c.rbegin(), c.rend()}; } template < typename Key, typename Mapped, typename Hasher, typename KeyEqual, typename Alloc> class F14FastMap : public std::conditional_t< sizeof(std::pair) < 24, F14ValueMap, f14::detail::F14VectorMapImpl< Key, Mapped, Hasher, KeyEqual, Alloc, std::true_type>> { using Super = std::conditional_t< sizeof(std::pair) < 24, F14ValueMap, f14::detail::F14VectorMapImpl< Key, Mapped, Hasher, KeyEqual, Alloc, std::true_type>>; public: using typename Super::value_type; F14FastMap() = default; using Super::Super; F14FastMap& operator=(std::initializer_list ilist) { Super::operator=(ilist); return *this; } void swap(F14FastMap& rhs) noexcept(Super::Policy::kSwapIsNoexcept) { this->table_.swap(rhs.table_); } }; } // namespace folly #else // !if FOLLY_F14_VECTOR_INTRINSICS_AVAILABLE //////// Compatibility for unsupported platforms (not x86_64 and not aarch64) #include #endif // if FOLLY_F14_VECTOR_INTRINSICS_AVAILABLE else namespace folly { namespace f14 { namespace detail { template bool mapsEqual(M const& lhs, M const& rhs) { if (lhs.size() != rhs.size()) { return false; } for (auto& kv : lhs) { if (!rhs.containsEqualValue(kv)) { return false; } } return true; } } // namespace detail } // namespace f14 template bool operator==( F14ValueMap const& lhs, F14ValueMap const& rhs) { return mapsEqual(lhs, rhs); } template bool operator!=( F14ValueMap const& lhs, F14ValueMap const& rhs) { return !(lhs == rhs); } template bool operator==( F14NodeMap const& lhs, F14NodeMap const& rhs) { return mapsEqual(lhs, rhs); } template bool operator!=( F14NodeMap const& lhs, F14NodeMap const& rhs) { return !(lhs == rhs); } template bool operator==( F14VectorMap const& lhs, F14VectorMap const& rhs) { return mapsEqual(lhs, rhs); } template bool operator!=( F14VectorMap const& lhs, F14VectorMap const& rhs) { return !(lhs == rhs); } template bool operator==( F14FastMap const& lhs, F14FastMap const& rhs) { return mapsEqual(lhs, rhs); } template bool operator!=( F14FastMap const& lhs, F14FastMap const& rhs) { return !(lhs == rhs); } template void swap( F14ValueMap& lhs, F14ValueMap& rhs) noexcept(noexcept(lhs.swap(rhs))) { lhs.swap(rhs); } template void swap( F14NodeMap& lhs, F14NodeMap& rhs) noexcept(noexcept(lhs.swap(rhs))) { lhs.swap(rhs); } template void swap( F14VectorMap& lhs, F14VectorMap& rhs) noexcept(noexcept(lhs.swap(rhs))) { lhs.swap(rhs); } template void swap( F14FastMap& lhs, F14FastMap& rhs) noexcept(noexcept(lhs.swap(rhs))) { lhs.swap(rhs); } template < typename K, typename M, typename H, typename E, typename A, typename Pred> void erase_if(F14ValueMap& c, Pred pred) { f14::detail::erase_if_impl(c, pred); } template < typename K, typename M, typename H, typename E, typename A, typename Pred> void erase_if(F14NodeMap& c, Pred pred) { f14::detail::erase_if_impl(c, pred); } template < typename K, typename M, typename H, typename E, typename A, typename Pred> void erase_if(F14VectorMap& c, Pred pred) { f14::detail::erase_if_impl(c, pred); } template < typename K, typename M, typename H, typename E, typename A, typename Pred> void erase_if(F14FastMap& c, Pred pred) { f14::detail::erase_if_impl(c, pred); } } // namespace folly