consul/lib/ttlcache/eviction.go

202 lines
5.3 KiB
Go

/*
Package ttlcache provides an ExpiryHeap that can be used by a cache to track the
expiration time of its entries. When an expiry is reached the Timer will fire
and the entry can be removed.
*/
package ttlcache
import (
"container/heap"
"time"
)
// Entry in the ExpiryHeap, tracks the index and expiry time of an item in a
// ttl cache.
type Entry struct {
key string
expiry time.Time
heapIndex int
}
// NotIndexed indicates that the entry does not exist in the heap. Either because
// it is nil, or because it was removed.
const NotIndexed = -1
// Index returns the index of this entry within the heap.
func (e *Entry) Index() int {
if e == nil {
return NotIndexed
}
return e.heapIndex
}
// Key returns the key for the entry in the heap.
func (e *Entry) Key() string {
return e.key
}
// ExpiryHeap is a heap that is ordered by the expiry time of entries. It may
// be used by a cache or storage to expiry items after a TTL.
//
// ExpiryHeap expects the caller to synchronize calls to most of its methods. This
// is necessary because the cache needs to ensure that updates to both its
// storage and the ExpiryHeap are synchronized.
type ExpiryHeap struct {
entries []*Entry
// NotifyCh is sent a value whenever the 0 index value of the heap
// changes. This can be used to detect when the earliest value
// changes.
NotifyCh chan struct{}
}
// NewExpiryHeap creates and returns a new ExpiryHeap.
func NewExpiryHeap() *ExpiryHeap {
h := &ExpiryHeap{NotifyCh: make(chan struct{}, 1)}
heap.Init((*entryHeap)(h))
return h
}
// Add an entry to the heap.
//
// Must be synchronized by the caller.
func (h *ExpiryHeap) Add(key string, expiry time.Duration) *Entry {
entry := &Entry{
key: key,
expiry: time.Now().Add(expiry),
// Set the initial heap index to the last index. If the entry is swapped it
// will have the correct index set, and if it remains at the end the last
// index will be correct.
heapIndex: len(h.entries),
}
heap.Push((*entryHeap)(h), entry)
if entry.heapIndex == 0 {
h.notify()
}
return entry
}
// Update the entry that is currently at idx with the new expiry time, if the new
// expiry time is further into the future. The heap will be rebalanced after the
// entry is updated. If the new expiry time is earlier than the existing expiry
// time than the expiry is not modified.
//
// Must be synchronized by the caller.
func (h *ExpiryHeap) Update(idx int, expiry time.Duration) {
if idx == NotIndexed {
// the previous entry did not have a valid index, its not in the heap
return
}
entry := h.entries[idx]
newExpiry := time.Now().Add(expiry)
// Ignore the new expiry if the time is earlier than the existing expiry.
if entry.expiry.After(newExpiry) {
return
}
entry.expiry = newExpiry
heap.Fix((*entryHeap)(h), idx)
if idx == 0 || entry.heapIndex == 0 {
h.notify()
}
}
// Remove the entry at idx from the heap.
//
// Must be synchronized by the caller.
func (h *ExpiryHeap) Remove(idx int) {
entry := h.entries[idx]
heap.Remove((*entryHeap)(h), idx)
// A goroutine which is fetching a new value will have a reference to this
// entry. When it re-acquires the lock it needs to be informed that
// the entry was expired while it was fetching. Setting heapIndex to -1
// indicates that the entry is no longer in the heap, and must be re-added.
entry.heapIndex = NotIndexed
if idx == 0 {
h.notify()
}
}
type entryHeap ExpiryHeap
func (h *entryHeap) Len() int { return len(h.entries) }
func (h *entryHeap) Swap(i, j int) {
h.entries[i], h.entries[j] = h.entries[j], h.entries[i]
h.entries[i].heapIndex = i
h.entries[j].heapIndex = j
}
func (h *entryHeap) Less(i, j int) bool {
// The usage of Before here is important (despite being obvious):
// this function uses the monotonic time that should be available
// on the time.Time value so the heap is immune to wall clock changes.
return h.entries[i].expiry.Before(h.entries[j].expiry)
}
// heap.Interface, this isn't expected to be called directly.
func (h *entryHeap) Push(x interface{}) {
h.entries = append(h.entries, x.(*Entry))
}
// heap.Interface, this isn't expected to be called directly.
func (h *entryHeap) Pop() interface{} {
n := len(h.entries)
entries := h.entries
last := entries[n-1]
h.entries = entries[0 : n-1]
return last
}
// notify the timer that the head value has changed, so the expiry time has
// also likely changed.
func (h *ExpiryHeap) notify() {
// Send to channel without blocking. Skips sending if there is already
// an item in the buffered channel.
select {
case h.NotifyCh <- struct{}{}:
default:
}
}
// Next returns a Timer that waits until the first entry in the heap expires.
//
// Must be synchronized by the caller.
func (h *ExpiryHeap) Next() Timer {
if len(h.entries) == 0 {
return Timer{}
}
entry := h.entries[0]
return Timer{
timer: time.NewTimer(time.Until(entry.expiry)),
Entry: entry,
}
}
// Timer provides a channel to block on. When the Wait channel receives an
// item the Timer.Entry has expired. The caller is expected to call
// ExpiryHeap.Remove with the Entry.Index().
//
// The caller is responsible for calling Stop to stop the timer if the timer has
// not fired.
type Timer struct {
timer *time.Timer
Entry *Entry
}
func (t *Timer) Wait() <-chan time.Time {
if t.timer == nil {
return nil
}
return t.timer.C
}
func (t *Timer) Stop() {
if t.timer != nil {
t.timer.Stop()
}
}