// Copyright 2012 The Chromium Authors // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef NET_BASE_PRIORITY_QUEUE_H_ #define NET_BASE_PRIORITY_QUEUE_H_ #include #include #include #include #include #include "base/check_op.h" #include "base/functional/bind.h" #include "base/functional/callback.h" #include "base/threading/thread_checker.h" #if !defined(NDEBUG) #include #endif namespace net { // A simple priority queue. The order of values is by priority and then FIFO. // Unlike the std::priority_queue, this implementation allows erasing elements // from the queue, and all operations are O(p) time for p priority levels. // The queue is agnostic to priority ordering (whether 0 precedes 1). // If the highest priority is 0, FirstMin() returns the first in order. // // In debug-mode, the internal queues store (id, value) pairs where id is used // to validate Pointers. // template class PriorityQueue { private: // This section is up-front for Pointer only. #if !defined(NDEBUG) typedef std::list > List; #else typedef std::list List; #endif public: typedef uint32_t Priority; // A pointer to a value stored in the queue. The pointer becomes invalid // when the queue is destroyed or cleared, or the value is erased. class Pointer { public: // Constructs a null pointer. Pointer() : priority_(kNullPriority) { #if !defined(NDEBUG) id_ = static_cast(-1); #endif // TODO(syzm) // An uninitialized iterator behaves like an uninitialized pointer as per // the STL docs. The fix below is ugly and should possibly be replaced // with a better approach. iterator_ = dummy_empty_list_.end(); } Pointer(const Pointer& p) : priority_(p.priority_), iterator_(p.iterator_) { #if !defined(NDEBUG) id_ = p.id_; #endif } Pointer& operator=(const Pointer& p) { // Self-assignment is benign. priority_ = p.priority_; iterator_ = p.iterator_; #if !defined(NDEBUG) id_ = p.id_; #endif return *this; } bool is_null() const { return priority_ == kNullPriority; } Priority priority() const { return priority_; } #if !defined(NDEBUG) const T& value() const { return iterator_->second; } #else const T& value() const { return *iterator_; } #endif // Comparing to Pointer from a different PriorityQueue is undefined. bool Equals(const Pointer& other) const { return (priority_ == other.priority_) && (iterator_ == other.iterator_); } void Reset() { *this = Pointer(); } private: friend class PriorityQueue; // Note that we need iterator and not const_iterator to pass to // List::erase. When C++11 is turned on for Chromium, this could // be changed to const_iterator and the const_casts in the rest of // the file can be removed. typedef typename PriorityQueue::List::iterator ListIterator; static const Priority kNullPriority = static_cast(-1); // It is guaranteed that Pointer will treat |iterator| as a // const_iterator. Pointer(Priority priority, const ListIterator& iterator) : priority_(priority), iterator_(iterator) { #if !defined(NDEBUG) id_ = iterator_->first; #endif } Priority priority_; ListIterator iterator_; // The STL iterators when uninitialized are like uninitialized pointers // which cause crashes when assigned to other iterators. We need to // initialize a NULL iterator to the end of a valid list. List dummy_empty_list_; #if !defined(NDEBUG) // Used by the queue to check if a Pointer is valid. unsigned id_; #endif }; // Creates a new queue for |num_priorities|. explicit PriorityQueue(Priority num_priorities) : lists_(num_priorities) { #if !defined(NDEBUG) next_id_ = 0; #endif } PriorityQueue(const PriorityQueue&) = delete; PriorityQueue& operator=(const PriorityQueue&) = delete; ~PriorityQueue() { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); } // Adds |value| with |priority| to the queue. Returns a pointer to the // created element. Pointer Insert(T value, Priority priority) { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); DCHECK_LT(priority, lists_.size()); ++size_; List& list = lists_[priority]; #if !defined(NDEBUG) unsigned id = next_id_; valid_ids_.insert(id); ++next_id_; list.emplace_back(id, std::move(value)); #else list.emplace_back(std::move(value)); #endif return Pointer(priority, std::prev(list.end())); } // Adds |value| with |priority| to the queue. Returns a pointer to the // created element. Pointer InsertAtFront(T value, Priority priority) { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); DCHECK_LT(priority, lists_.size()); ++size_; List& list = lists_[priority]; #if !defined(NDEBUG) unsigned id = next_id_; valid_ids_.insert(id); ++next_id_; list.emplace_front(std::pair(id, std::move(value))); #else list.emplace_front(std::move(value)); #endif return Pointer(priority, list.begin()); } // Removes the value pointed by |pointer| from the queue. All pointers to this // value including |pointer| become invalid. Returns the erased value. T Erase(const Pointer& pointer) { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); DCHECK_LT(pointer.priority_, lists_.size()); DCHECK_GT(size_, 0u); #if !defined(NDEBUG) DCHECK_EQ(1u, valid_ids_.erase(pointer.id_)); DCHECK_EQ(pointer.iterator_->first, pointer.id_); T erased = std::move(pointer.iterator_->second); #else T erased = std::move(*pointer.iterator_); #endif --size_; lists_[pointer.priority_].erase(pointer.iterator_); return erased; } // Returns a pointer to the first value of minimum priority or a null-pointer // if empty. Pointer FirstMin() const { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); for (size_t i = 0; i < lists_.size(); ++i) { List* list = const_cast(&lists_[i]); if (!list->empty()) return Pointer(i, list->begin()); } return Pointer(); } // Returns a pointer to the last value of minimum priority or a null-pointer // if empty. Pointer LastMin() const { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); for (size_t i = 0; i < lists_.size(); ++i) { List* list = const_cast(&lists_[i]); if (!list->empty()) return Pointer(i, --list->end()); } return Pointer(); } // Returns a pointer to the first value of maximum priority or a null-pointer // if empty. Pointer FirstMax() const { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); for (size_t i = lists_.size(); i > 0; --i) { size_t index = i - 1; List* list = const_cast(&lists_[index]); if (!list->empty()) return Pointer(index, list->begin()); } return Pointer(); } // Returns a pointer to the last value of maximum priority or a null-pointer // if empty. Pointer LastMax() const { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); for (size_t i = lists_.size(); i > 0; --i) { size_t index = i - 1; List* list = const_cast(&lists_[index]); if (!list->empty()) return Pointer(index, --list->end()); } return Pointer(); } // Given an ordering of the values in this queue by decreasing priority and // then FIFO, returns a pointer to the value following the value of the given // pointer (which must be non-NULL). I.e., gets the next element in decreasing // priority, then FIFO order. If the given pointer is already pointing at the // last value, returns a null Pointer. // // (One could also implement GetNextTowardsFirstMin() [decreasing priority, // then reverse FIFO] as well as GetNextTowards{First,Last}Max() [increasing // priority, then {,reverse} FIFO].) Pointer GetNextTowardsLastMin(const Pointer& pointer) const { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); DCHECK(!pointer.is_null()); DCHECK_LT(pointer.priority_, lists_.size()); typename Pointer::ListIterator it = pointer.iterator_; Priority priority = pointer.priority_; DCHECK(it != lists_[priority].end()); ++it; while (it == lists_[priority].end()) { if (priority == 0u) { DCHECK(pointer.Equals(LastMin())); return Pointer(); } --priority; it = const_cast(&lists_[priority])->begin(); } return Pointer(priority, it); } // Given an ordering of the values in this queue by decreasing priority and // then FIFO, returns a pointer to the value preceding the value of the given // pointer (which must be non-NULL). I.e., gets the next element in increasing // priority, then reverse FIFO order. If the given pointer is already pointing // at the first value, returns a null Pointer. Pointer GetPreviousTowardsFirstMax(const Pointer& pointer) const { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); DCHECK(!pointer.is_null()); DCHECK_LT(pointer.priority_, lists_.size()); typename Pointer::ListIterator it = pointer.iterator_; Priority priority = pointer.priority_; DCHECK(it != lists_[priority].end()); while (it == lists_[priority].begin()) { if (priority == num_priorities() - 1) { DCHECK(pointer.Equals(FirstMax())); return Pointer(); } ++priority; it = const_cast(&lists_[priority])->end(); } return Pointer(priority, std::prev(it)); } // Checks whether |lhs| is closer in the queue to the first max element than // |rhs|. Assumes that both Pointers refer to elements in this PriorityQueue. bool IsCloserToFirstMaxThan(const Pointer& lhs, const Pointer& rhs) { if (lhs.Equals(rhs)) return false; if (lhs.priority_ == rhs.priority_) { // Traverse list starting from lhs and see if we find rhs. for (auto it = lhs.iterator_; it != lists_[lhs.priority_].end(); ++it) { if (it == rhs.iterator_) return true; } return false; } return lhs.priority_ > rhs.priority_; } // Checks whether |lhs| is closer in the queue to the last min element than // |rhs|. Assumes that both Pointers refer to elements in this PriorityQueue. bool IsCloserToLastMinThan(const Pointer& lhs, const Pointer& rhs) { return !lhs.Equals(rhs) && !IsCloserToFirstMaxThan(lhs, rhs); } // Finds the first element (with respect to decreasing priority, then FIFO // order) which matches the given predicate. Pointer FindIf(const base::RepeatingCallback& pred) { for (auto pointer = FirstMax(); !pointer.is_null(); pointer = GetNextTowardsLastMin(pointer)) { if (pred.Run(pointer.value())) return pointer; } return Pointer(); } // Empties the queue. All pointers become invalid. void Clear() { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); for (size_t i = 0; i < lists_.size(); ++i) { lists_[i].clear(); } #if !defined(NDEBUG) valid_ids_.clear(); #endif size_ = 0u; } // Returns the number of priorities the queue supports. size_t num_priorities() const { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); return lists_.size(); } bool empty() const { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); return size_ == 0; } // Returns number of queued values. size_t size() const { DCHECK_CALLED_ON_VALID_THREAD(thread_checker_); return size_; } private: typedef std::vector ListVector; #if !defined(NDEBUG) unsigned next_id_; std::unordered_set valid_ids_; #endif ListVector lists_; size_t size_ = 0; THREAD_CHECKER(thread_checker_); }; } // namespace net #endif // NET_BASE_PRIORITY_QUEUE_H_