// Package queue provides Vault plugins with a Priority Queue. It can be used // as an in-memory list of queue.Item sorted by their priority, and offers // methods to find or remove items by their key. Internally it uses // container/heap; see Example Priority Queue: // https://golang.org/pkg/container/heap/#example__priorityQueue package queue import ( "container/heap" "errors" "sync" "github.com/mitchellh/copystructure" ) // ErrEmpty is returned for queues with no items var ErrEmpty = errors.New("queue is empty") // ErrDuplicateItem is returned when the queue attmepts to push an item to a key that // already exists. The queue does not attempt to update, instead returns this // error. If an Item needs to be updated or replaced, pop the item first. var ErrDuplicateItem = errors.New("duplicate item") // New initializes the internal data structures and returns a new // PriorityQueue func New() *PriorityQueue { pq := PriorityQueue{ data: make(queue, 0), dataMap: make(map[string]*Item), } heap.Init(&pq.data) return &pq } // PriorityQueue facilitates queue of Items, providing Push, Pop, and // PopByKey convenience methods. The ordering (priority) is an int64 value // with the smallest value is the highest priority. PriorityQueue maintains both // an internal slice for the queue as well as a map of the same items with their // keys as the index. This enables users to find specific items by key. The map // must be kept in sync with the data slice. // See https://golang.org/pkg/container/heap/#example__priorityQueue type PriorityQueue struct { // data is the internal structure that holds the queue, and is operated on by // heap functions data queue // dataMap represents all the items in the queue, with unique indexes, used // for finding specific items. dataMap is kept in sync with the data slice dataMap map[string]*Item // lock is a read/write mutex, and used to facilitate read/write locks on the // data and dataMap fields lock sync.RWMutex } // queue is the internal data structure used to satisfy heap.Interface. This // prevents users from calling Pop and Push heap methods directly type queue []*Item // Item is something managed in the priority queue type Item struct { // Key is a unique string used to identify items in the internal data map Key string // Value is an unspecified type that implementations can use to store // information Value interface{} // Priority determines ordering in the queue, with the lowest value being the // highest priority Priority int64 // index is an internal value used by the heap package, and should not be // modified by any consumer of the priority queue index int } // Len returns the count of items in the Priority Queue func (pq *PriorityQueue) Len() int { pq.lock.RLock() defer pq.lock.RUnlock() return pq.data.Len() } // Pop pops the highest priority item from the queue. This is a // wrapper/convenience method that calls heap.Pop, so consumers do not need to // invoke heap functions directly func (pq *PriorityQueue) Pop() (*Item, error) { pq.lock.Lock() defer pq.lock.Unlock() if pq.data.Len() == 0 { return nil, ErrEmpty } item := heap.Pop(&pq.data).(*Item) delete(pq.dataMap, item.Key) return item, nil } // Push pushes an item on to the queue. This is a wrapper/convenience // method that calls heap.Push, so consumers do not need to invoke heap // functions directly. Items must have unique Keys, and Items in the queue // cannot be updated. To modify an Item, users must first remove it and re-push // it after modifications func (pq *PriorityQueue) Push(i *Item) error { if i == nil || i.Key == "" { return errors.New("error adding item: Item Key is required") } pq.lock.Lock() defer pq.lock.Unlock() if _, ok := pq.dataMap[i.Key]; ok { return ErrDuplicateItem } // Copy the item value(s) so that modifications to the source item does not // affect the item on the queue clone, err := copystructure.Copy(i) if err != nil { return err } pq.dataMap[i.Key] = clone.(*Item) heap.Push(&pq.data, clone) return nil } // PopByKey searches the queue for an item with the given key and removes it // from the queue if found. Returns nil if not found. This method must fix the // queue after removing any key. func (pq *PriorityQueue) PopByKey(key string) (*Item, error) { pq.lock.Lock() defer pq.lock.Unlock() item, ok := pq.dataMap[key] if !ok { return nil, nil } // Remove the item the heap and delete it from the dataMap itemRaw := heap.Remove(&pq.data, item.index) delete(pq.dataMap, key) if itemRaw != nil { if i, ok := itemRaw.(*Item); ok { return i, nil } } return nil, nil } // Len returns the number of items in the queue data structure. Do not use this // method directly on the queue, use PriorityQueue.Len() instead. func (q queue) Len() int { return len(q) } // Less returns whether the Item with index i should sort before the Item with // index j in the queue. This method is used by the queue to determine priority // internally; the Item with the lower value wins. (priority zero is higher // priority than 1). The priority of Items with equal values is undetermined. func (q queue) Less(i, j int) bool { return q[i].Priority < q[j].Priority } // Swap swaps things in-place; part of sort.Interface func (q queue) Swap(i, j int) { q[i], q[j] = q[j], q[i] q[i].index = i q[j].index = j } // Push is used by heap.Interface to push items onto the heap. This method is // invoked by container/heap, and should not be used directly. // See: https://golang.org/pkg/container/heap/#Interface func (q *queue) Push(x interface{}) { n := len(*q) item := x.(*Item) item.index = n *q = append(*q, item) } // Pop is used by heap.Interface to pop items off of the heap. This method is // invoked by container/heap, and should not be used directly. // See: https://golang.org/pkg/container/heap/#Interface func (q *queue) Pop() interface{} { old := *q n := len(old) item := old[n-1] old[n-1] = nil // avoid memory leak item.index = -1 // for safety *q = old[0 : n-1] return item }