// ***************************************************************************** // * This file is part of the FreeFileSync project. It is distributed under * // * GNU General Public License: http://www.gnu.org/licenses/gpl-3.0 * // * Copyright (C) Zenju (zenju AT freefilesync DOT org) - All Rights Reserved * // ***************************************************************************** #ifndef FIXED_LIST_H_01238467085684139453534 #define FIXED_LIST_H_01238467085684139453534 #include #include #include "stl_tools.h" namespace zen { //std::list(C++11)-like class for inplace element construction supporting non-copyable/non-movable types //-> no iterator invalidation after emplace_back() template class FixedList { struct Node { template Node(Args&& ... args) : val(std::forward(args)...) {} Node* next = nullptr; //singly-linked list is sufficient T val; }; public: FixedList() {} ~FixedList() { clear(); } template class FixedIterator : public std::iterator { public: FixedIterator(NodeT* it = nullptr) : it_(it) {} FixedIterator& operator++() { it_ = it_->next; return *this; } inline friend bool operator==(const FixedIterator& lhs, const FixedIterator& rhs) { return lhs.it_ == rhs.it_; } inline friend bool operator!=(const FixedIterator& lhs, const FixedIterator& rhs) { return !(lhs == rhs); } U& operator* () const { return it_->val; } U* operator->() const { return &it_->val; } private: NodeT* it_; }; using value_type = T; using iterator = FixedIterator< Node, T>; using const_iterator = FixedIterator; using reference = T&; using const_reference = const T&; iterator begin() { return firstInsert_; } iterator end () { return iterator(); } const_iterator begin() const { return firstInsert_; } const_iterator end () const { return const_iterator(); } //const_iterator cbegin() const { return firstInsert_; } //const_iterator cend () const { return const_iterator(); } reference front() { return firstInsert_->val; } const_reference front() const { return firstInsert_->val; } reference& back() { return lastInsert_->val; } const_reference& back() const { return lastInsert_->val; } template void emplace_back(Args&& ... args) { Node* newNode = new Node(std::forward(args)...); if (!lastInsert_) { assert(!firstInsert_ && sz_ == 0); firstInsert_ = lastInsert_ = newNode; } else { assert(lastInsert_->next == nullptr); lastInsert_->next = newNode; lastInsert_ = newNode; } ++sz_; } template void remove_if(Predicate pred) { Node* prev = nullptr; Node* ptr = firstInsert_; while (ptr) if (pred(ptr->val)) { Node* next = ptr->next; delete ptr; assert(sz_ > 0); --sz_; ptr = next; if (prev) prev->next = next; else firstInsert_ = next; if (!next) lastInsert_ = prev; } else { prev = ptr; ptr = ptr->next; } } void clear() { Node* ptr = firstInsert_; while (ptr) { Node* next = ptr->next; delete ptr; ptr = next; } sz_ = 0; firstInsert_ = lastInsert_ = nullptr; } bool empty() const { return sz_ == 0; } size_t size() const { return sz_; } void swap(FixedList& other) { std::swap(firstInsert_, other.firstInsert_); std::swap(lastInsert_, other.lastInsert_); std::swap(sz_, other.sz_); } private: FixedList (const FixedList&) = delete; FixedList& operator=(const FixedList&) = delete; Node* firstInsert_ = nullptr; Node* lastInsert_ = nullptr; //point to last insertion; required by efficient emplace_back() size_t sz_ = 0; }; //just as fast as FixedList, but simpler, more CPU-cache-friendly => superseeds FixedList! template class FixedVector { public: FixedVector() {} /* class EndIterator {}; //just like FixedList: no iterator invalidation after emplace_back() template class FixedIterator : public std::iterator //could make this random-access if needed { public: FixedIterator(std::vector>& cont, size_t pos) : cont_(cont), pos_(pos) {} FixedIterator& operator++() { ++pos_; return *this; } inline friend bool operator==(const FixedIterator& lhs, EndIterator) { return lhs.pos_ == lhs.cont_.size(); } inline friend bool operator!=(const FixedIterator& lhs, EndIterator) { return !(lhs == EndIterator()); } V& operator* () const { return *cont_[pos_]; } V* operator->() const { return &*cont_[pos_]; } private: std::vector>& cont_; size_t pos_ = 0; }; */ template class FixedIterator : public std::iterator //could make this bidirectional if needed { public: FixedIterator(IterImpl it) : it_(it) {} FixedIterator& operator++() { ++it_; return *this; } inline friend bool operator==(const FixedIterator& lhs, const FixedIterator& rhs) { return lhs.it_ == rhs.it_; } inline friend bool operator!=(const FixedIterator& lhs, const FixedIterator& rhs) { return !(lhs == rhs); } V& operator* () const { return **it_; } V* operator->() const { return &** it_; } private: IterImpl it_; //TODO: avoid iterator invalidation after emplace_back(); caveat: end() must not store old length! }; using value_type = T; using iterator = FixedIterator>::iterator, T>; using const_iterator = FixedIterator>::const_iterator, const T>; using reference = T&; using const_reference = const T&; iterator begin() { return items_.begin(); } iterator end () { return items_.end (); } const_iterator begin() const { return items_.begin(); } const_iterator end () const { return items_.end (); } reference front() { return *items_.front(); } const_reference front() const { return *items_.front(); } reference& back() { return *items_.back(); } const_reference& back() const { return *items_.back(); } template void emplace_back(Args&& ... args) { items_.push_back(std::make_unique(std::forward(args)...)); } template void remove_if(Predicate pred) { erase_if(items_, [&](const std::unique_ptr& p) { return pred(*p); }); } void clear() { items_.clear(); } bool empty() const { return items_.empty(); } size_t size () const { return items_.size(); } void swap(FixedVector& other) { items_.swap(other.items_); } private: FixedVector (const FixedVector&) = delete; FixedVector& operator=(const FixedVector&) = delete; std::vector> items_; }; } #endif //FIXED_LIST_H_01238467085684139453534