/* * Copyright 2012-present Facebook, Inc. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #pragma once #include #include #include #include #include #include #include #include #include #include #include /** * Code that aids in storing data aligned on block (possibly cache-line) * boundaries, perhaps with padding. * * Class Node represents one block. Given an iterator to a container of * Node, class Iterator encapsulates an iterator to the underlying elements. * Adaptor converts a sequence of Node into a sequence of underlying elements * (not fully compatible with STL container requirements, see comments * near the Node class declaration). */ namespace folly { namespace padded { /** * A Node is a fixed-size container of as many objects of type T as would * fit in a region of memory of size NS. The last NS % sizeof(T) * bytes are ignored and uninitialized. * * Node only works for trivial types, which is usually not a concern. This * is intentional: Node itself is trivial, which means that it can be * serialized / deserialized using a simple memcpy. */ template class Node; namespace detail { // Shortcut to avoid writing the long enable_if expression every time template struct NodeValid; template struct NodeValid< T, NS, typename std::enable_if<( std::is_trivial::value && sizeof(T) <= NS && NS % alignof(T) == 0)>::type> { typedef void type; }; } // namespace detail template class Node::type> { public: typedef T value_type; static constexpr size_t kNodeSize = NS; static constexpr size_t kElementCount = NS / sizeof(T); static constexpr size_t kPaddingBytes = NS % sizeof(T); T* data() { return storage_.data; } const T* data() const { return storage_.data; } bool operator==(const Node& other) const { return memcmp(data(), other.data(), sizeof(T) * kElementCount) == 0; } bool operator!=(const Node& other) const { return !(*this == other); } /** * Return the number of nodes needed to represent n values. Rounds up. */ static constexpr size_t nodeCount(size_t n) { return (n + kElementCount - 1) / kElementCount; } /** * Return the total byte size needed to represent n values, rounded up * to the nearest full node. */ static constexpr size_t paddedByteSize(size_t n) { return nodeCount(n) * NS; } /** * Return the number of bytes used for padding n values. * Note that, even if n is a multiple of kElementCount, this may * return non-zero if kPaddingBytes != 0, as the padding at the end of * the last node is not included in the result. */ static constexpr size_t paddingBytes(size_t n) { return ( n ? (kPaddingBytes + (kElementCount - 1 - (n - 1) % kElementCount) * sizeof(T)) : 0); } /** * Return the minimum byte size needed to represent n values. * Does not round up. Even if n is a multiple of kElementCount, this * may be different from paddedByteSize() if kPaddingBytes != 0, as * the padding at the end of the last node is not included in the result. * Note that the calculation below works for n=0 correctly (returns 0). */ static constexpr size_t unpaddedByteSize(size_t n) { return paddedByteSize(n) - paddingBytes(n); } private: union Storage { unsigned char bytes[NS]; T data[kElementCount]; } storage_; }; // We must define kElementCount and kPaddingBytes to work around a bug // in gtest that odr-uses them. template constexpr size_t Node::type>::kNodeSize; template constexpr size_t Node::type>::kElementCount; template constexpr size_t Node::type>::kPaddingBytes; template class Iterator; namespace detail { template struct padded_emplace_back_or_push_back_ { static decltype(auto) go(Container& container, Args&&... args) { using Value = typename Container::value_type; return container.push_back(Value(std::forward(args)...)); } }; template struct padded_emplace_back_or_push_back_< void_t().emplace_back(std::declval()...))>, Container, Args...> { static decltype(auto) go(Container& container, Args&&... args) { return container.emplace_back(std::forward(args)...); } }; template decltype(auto) padded_emplace_back_or_push_back( Container& container, Args&&... args) { using impl = padded_emplace_back_or_push_back_; return impl::go(container, std::forward(args)...); } // Helper class to transfer the constness from From (a lvalue reference) // and create a lvalue reference to To. // // TransferReferenceConstness -> const int& // TransferReferenceConstness -> int& // TransferReferenceConstness -> const int& template struct TransferReferenceConstness; template struct TransferReferenceConstness< From, To, typename std::enable_if::type>::value>::type> { typedef typename std::add_lvalue_reference< typename std::add_const::type>::type type; }; template struct TransferReferenceConstness< From, To, typename std::enable_if::type>::value>::type> { typedef typename std::add_lvalue_reference::type type; }; // Helper class template to define a base class for Iterator (below) and save // typing. template struct IteratorBase { typedef boost::iterator_adaptor< // CRTC Iterator, // Base iterator type Iter, // Value type typename std::iterator_traits::value_type::value_type, // Category or traversal boost::use_default, // Reference type typename detail::TransferReferenceConstness< typename std::iterator_traits::reference, typename std::iterator_traits::value_type::value_type>::type> type; }; } // namespace detail /** * Wrapper around iterators to Node to return iterators to the underlying * node elements. */ template class Iterator : public detail::IteratorBase::type { typedef typename detail::IteratorBase::type Super; public: typedef typename std::iterator_traits::value_type Node; Iterator() : pos_(0) {} explicit Iterator(Iter base) : Super(base), pos_(0) {} // Return the current node and the position inside the node const Node& node() const { return *this->base_reference(); } size_t pos() const { return pos_; } private: typename Super::reference dereference() const { return (*this->base_reference()).data()[pos_]; } bool equal(const Iterator& other) const { return ( this->base_reference() == other.base_reference() && pos_ == other.pos_); } void advance(typename Super::difference_type n) { constexpr ssize_t elementCount = Node::kElementCount; // signed! ssize_t newPos = pos_ + n; if (newPos >= 0 && newPos < elementCount) { pos_ = newPos; return; } ssize_t nblocks = newPos / elementCount; newPos %= elementCount; if (newPos < 0) { --nblocks; // negative newPos += elementCount; } this->base_reference() += nblocks; pos_ = newPos; } void increment() { if (++pos_ == Node::kElementCount) { ++this->base_reference(); pos_ = 0; } } void decrement() { if (--pos_ == -1) { --this->base_reference(); pos_ = Node::kElementCount - 1; } } typename Super::difference_type distance_to(const Iterator& other) const { constexpr ssize_t elementCount = Node::kElementCount; // signed! ssize_t nblocks = std::distance(this->base_reference(), other.base_reference()); return nblocks * elementCount + (other.pos_ - pos_); } friend class boost::iterator_core_access; ssize_t pos_; // signed for easier advance() implementation }; /** * Given a container to Node, return iterators to the first element in * the first Node / one past the last element in the last Node. * Note that the last node is assumed to be full; if that's not the case, * subtract from end() as appropriate. */ template Iterator cbegin(const Container& c) { return Iterator(std::begin(c)); } template Iterator cend(const Container& c) { return Iterator(std::end(c)); } template Iterator begin(const Container& c) { return cbegin(c); } template Iterator end(const Container& c) { return cend(c); } template Iterator begin(Container& c) { return Iterator(std::begin(c)); } template Iterator end(Container& c) { return Iterator(std::end(c)); } /** * Adaptor around a STL sequence container. * * Converts a sequence of Node into a sequence of its underlying elements * (with enough functionality to make it useful, although it's not fully * compatible with the STL containre requiremenets, see below). * * Provides iterators (of the same category as those of the underlying * container), size(), front(), back(), push_back(), pop_back(), and const / * non-const versions of operator[] (if the underlying container supports * them). Does not provide push_front() / pop_front() or arbitrary insert / * emplace / erase. Also provides reserve() / capacity() if supported by the * underlying container. * * Yes, it's called Adaptor, not Adapter, as that's the name used by the STL * and by boost. Deal with it. * * Internally, we hold a container of Node and the number of elements in * the last block. We don't keep empty blocks, so the number of elements in * the last block is always between 1 and Node::kElementCount (inclusive). * (this is true if the container is empty as well to make push_back() simpler, * see the implementation of the size() method for details). */ template class Adaptor { public: typedef typename Container::value_type Node; typedef typename Node::value_type value_type; typedef value_type& reference; typedef const value_type& const_reference; typedef Iterator iterator; typedef Iterator const_iterator; typedef typename const_iterator::difference_type difference_type; typedef typename Container::size_type size_type; static constexpr size_t kElementsPerNode = Node::kElementCount; // Constructors Adaptor() : lastCount_(Node::kElementCount) {} explicit Adaptor(Container c, size_t lastCount = Node::kElementCount) : c_(std::move(c)), lastCount_(lastCount) {} explicit Adaptor(size_t n, const value_type& value = value_type()) : c_(Node::nodeCount(n), fullNode(value)) { const auto count = n % Node::kElementCount; lastCount_ = count != 0 ? count : Node::kElementCount; } Adaptor(const Adaptor&) = default; Adaptor& operator=(const Adaptor&) = default; Adaptor(Adaptor&& other) noexcept : c_(std::move(other.c_)), lastCount_(other.lastCount_) { other.lastCount_ = Node::kElementCount; } Adaptor& operator=(Adaptor&& other) { if (this != &other) { c_ = std::move(other.c_); lastCount_ = other.lastCount_; other.lastCount_ = Node::kElementCount; } return *this; } // Iterators const_iterator cbegin() const { return const_iterator(c_.begin()); } const_iterator cend() const { auto it = const_iterator(c_.end()); if (lastCount_ != Node::kElementCount) { it -= (Node::kElementCount - lastCount_); } return it; } const_iterator begin() const { return cbegin(); } const_iterator end() const { return cend(); } iterator begin() { return iterator(c_.begin()); } iterator end() { auto it = iterator(c_.end()); if (lastCount_ != Node::kElementCount) { it -= difference_type(Node::kElementCount - lastCount_); } return it; } void swap(Adaptor& other) { using std::swap; swap(c_, other.c_); swap(lastCount_, other.lastCount_); } bool empty() const { return c_.empty(); } size_type size() const { return ( c_.empty() ? 0 : (c_.size() - 1) * Node::kElementCount + lastCount_); } size_type max_size() const { return ( (c_.max_size() <= std::numeric_limits::max() / Node::kElementCount) ? c_.max_size() * Node::kElementCount : std::numeric_limits::max()); } const value_type& front() const { assert(!empty()); return c_.front().data()[0]; } value_type& front() { assert(!empty()); return c_.front().data()[0]; } const value_type& back() const { assert(!empty()); return c_.back().data()[lastCount_ - 1]; } value_type& back() { assert(!empty()); return c_.back().data()[lastCount_ - 1]; } template void emplace_back(Args&&... args) { new (allocate_back()) value_type(std::forward(args)...); } void push_back(value_type x) { emplace_back(std::move(x)); } void pop_back() { assert(!empty()); if (--lastCount_ == 0) { c_.pop_back(); lastCount_ = Node::kElementCount; } } void clear() { c_.clear(); lastCount_ = Node::kElementCount; } void reserve(size_type n) { assert(n >= 0); c_.reserve(Node::nodeCount(n)); } size_type capacity() const { return c_.capacity() * Node::kElementCount; } const value_type& operator[](size_type idx) const { return c_[idx / Node::kElementCount].data()[idx % Node::kElementCount]; } value_type& operator[](size_type idx) { return c_[idx / Node::kElementCount].data()[idx % Node::kElementCount]; } /** * Return the underlying container and number of elements in the last block, * and clear *this. Useful when you want to process the data as Nodes * (again) and want to avoid copies. */ std::pair move() { std::pair p(std::move(c_), lastCount_); lastCount_ = Node::kElementCount; return std::move(p); } /** * Return a const reference to the underlying container and the current * number of elements in the last block. */ std::pair peek() const { return std::make_pair(std::cref(c_), lastCount_); } void padToFullNode(const value_type& padValue) { // the if is necessary because c_ may be empty so we can't call c_.back() if (lastCount_ != Node::kElementCount) { auto last = c_.back().data(); std::fill(last + lastCount_, last + Node::kElementCount, padValue); lastCount_ = Node::kElementCount; } } private: value_type* allocate_back() { if (lastCount_ == Node::kElementCount) { detail::padded_emplace_back_or_push_back(c_); lastCount_ = 0; } return &c_.back().data()[lastCount_++]; } static Node fullNode(const value_type& value) { Node n; std::fill(n.data(), n.data() + kElementsPerNode, value); return n; } Container c_; // container of Nodes size_t lastCount_; // number of elements in last Node }; } // namespace padded } // namespace folly