package lrucache import ( "container/heap" "sync" "sync/atomic" "time" "github.com/VictoriaMetrics/VictoriaMetrics/lib/bytesutil" "github.com/VictoriaMetrics/VictoriaMetrics/lib/cgroup" "github.com/VictoriaMetrics/VictoriaMetrics/lib/fasttime" "github.com/VictoriaMetrics/VictoriaMetrics/lib/timeutil" "github.com/cespare/xxhash/v2" ) // Cache caches Entry entries. // // Call NewCache() for creating new Cache. type Cache struct { shards []*cache cleanerMustStopCh chan struct{} cleanerStoppedCh chan struct{} } // NewCache creates new cache. // // Cache size in bytes is limited by the value returned by getMaxSizeBytes() callback. // Call MustStop() in order to free up resources occupied by Cache. func NewCache(getMaxSizeBytes func() int) *Cache { cpusCount := cgroup.AvailableCPUs() shardsCount := cgroup.AvailableCPUs() // Increase the number of shards with the increased number of available CPU cores. // This should reduce contention on per-shard mutexes. multiplier := cpusCount if multiplier > 16 { multiplier = 16 } shardsCount *= multiplier shards := make([]*cache, shardsCount) getMaxShardBytes := func() int { n := getMaxSizeBytes() return n / shardsCount } for i := range shards { shards[i] = newCache(getMaxShardBytes) } c := &Cache{ shards: shards, cleanerMustStopCh: make(chan struct{}), cleanerStoppedCh: make(chan struct{}), } go c.cleaner() return c } // MustStop frees up resources occupied by c. func (c *Cache) MustStop() { close(c.cleanerMustStopCh) <-c.cleanerStoppedCh } // GetEntry returns an Entry for the given key k from c. func (c *Cache) GetEntry(k string) Entry { idx := uint64(0) if len(c.shards) > 1 { h := hashUint64(k) idx = h % uint64(len(c.shards)) } shard := c.shards[idx] return shard.GetEntry(k) } // PutEntry puts the given Entry e under the given key k into c. func (c *Cache) PutEntry(k string, e Entry) { idx := uint64(0) if len(c.shards) > 1 { h := hashUint64(k) idx = h % uint64(len(c.shards)) } shard := c.shards[idx] shard.PutEntry(k, e) } // Len returns the number of blocks in the cache c. func (c *Cache) Len() int { n := 0 for _, shard := range c.shards { n += shard.Len() } return n } // SizeBytes returns an approximate size in bytes of all the blocks stored in the cache c. func (c *Cache) SizeBytes() int { n := 0 for _, shard := range c.shards { n += shard.SizeBytes() } return n } // SizeMaxBytes returns the max allowed size in bytes for c. func (c *Cache) SizeMaxBytes() int { n := 0 for _, shard := range c.shards { n += shard.SizeMaxBytes() } return n } // Requests returns the number of requests served by c. func (c *Cache) Requests() uint64 { n := uint64(0) for _, shard := range c.shards { n += shard.Requests() } return n } // Misses returns the number of cache misses for c. func (c *Cache) Misses() uint64 { n := uint64(0) for _, shard := range c.shards { n += shard.Misses() } return n } func (c *Cache) cleaner() { d := timeutil.AddJitterToDuration(time.Second * 53) ticker := time.NewTicker(d) defer ticker.Stop() for { select { case <-c.cleanerMustStopCh: close(c.cleanerStoppedCh) return case <-ticker.C: c.cleanByTimeout() } } } func (c *Cache) cleanByTimeout() { for _, shard := range c.shards { shard.cleanByTimeout() } } type cache struct { requests atomic.Uint64 misses atomic.Uint64 // sizeBytes contains an approximate size for all the blocks stored in the cache. sizeBytes atomic.Int64 // getMaxSizeBytes() is a callback, which returns the maximum allowed cache size in bytes. getMaxSizeBytes func() int // mu protects all the fields below. mu sync.Mutex // m contains cached entries m map[string]*cacheEntry // The heap for removing the least recently used entries from m. lah lastAccessHeap } func hashUint64(s string) uint64 { b := bytesutil.ToUnsafeBytes(s) return xxhash.Sum64(b) } // Entry is an item, which may be cached in the Cache. type Entry interface { // SizeBytes must return the approximate size of the given entry in bytes SizeBytes() int } type cacheEntry struct { // The timestamp in seconds for the last access to the given entry. lastAccessTime uint64 // heapIdx is the index for the entry in lastAccessHeap. heapIdx int // k contains the associated key for the given entry. k string // e contains the cached entry. e Entry } func newCache(getMaxSizeBytes func() int) *cache { var c cache c.getMaxSizeBytes = getMaxSizeBytes c.m = make(map[string]*cacheEntry) return &c } func (c *cache) updateSizeBytes(n int) { c.sizeBytes.Add(int64(n)) } func (c *cache) cleanByTimeout() { // Delete items accessed more than three minutes ago. // This time should be enough for repeated queries. lastAccessTime := fasttime.UnixTimestamp() - 3*60 c.mu.Lock() defer c.mu.Unlock() for len(c.lah) > 0 { if lastAccessTime < c.lah[0].lastAccessTime { break } c.removeLeastRecentlyAccessedItem() } } func (c *cache) GetEntry(k string) Entry { c.requests.Add(1) c.mu.Lock() defer c.mu.Unlock() ce := c.m[k] if ce == nil { c.misses.Add(1) return nil } currentTime := fasttime.UnixTimestamp() if ce.lastAccessTime != currentTime { ce.lastAccessTime = currentTime heap.Fix(&c.lah, ce.heapIdx) } return ce.e } func (c *cache) PutEntry(k string, e Entry) { c.mu.Lock() defer c.mu.Unlock() ce := c.m[k] if ce != nil { // The entry has been already registered by concurrent goroutine. return } ce = &cacheEntry{ lastAccessTime: fasttime.UnixTimestamp(), k: k, e: e, } heap.Push(&c.lah, ce) c.m[k] = ce c.updateSizeBytes(e.SizeBytes()) maxSizeBytes := c.getMaxSizeBytes() for c.SizeBytes() > maxSizeBytes && len(c.lah) > 0 { c.removeLeastRecentlyAccessedItem() } } func (c *cache) removeLeastRecentlyAccessedItem() { ce := c.lah[0] c.updateSizeBytes(-ce.e.SizeBytes()) delete(c.m, ce.k) heap.Pop(&c.lah) } func (c *cache) Len() int { c.mu.Lock() defer c.mu.Unlock() return len(c.m) } func (c *cache) SizeBytes() int { return int(c.sizeBytes.Load()) } func (c *cache) SizeMaxBytes() int { return c.getMaxSizeBytes() } func (c *cache) Requests() uint64 { return c.requests.Load() } func (c *cache) Misses() uint64 { return c.misses.Load() } // lastAccessHeap implements heap.Interface type lastAccessHeap []*cacheEntry func (lah *lastAccessHeap) Len() int { return len(*lah) } func (lah *lastAccessHeap) Swap(i, j int) { h := *lah a := h[i] b := h[j] a.heapIdx = j b.heapIdx = i h[i] = b h[j] = a } func (lah *lastAccessHeap) Less(i, j int) bool { h := *lah return h[i].lastAccessTime < h[j].lastAccessTime } func (lah *lastAccessHeap) Push(x interface{}) { e := x.(*cacheEntry) h := *lah e.heapIdx = len(h) *lah = append(h, e) } func (lah *lastAccessHeap) Pop() interface{} { h := *lah e := h[len(h)-1] // Remove the reference to deleted entry, so Go GC could free up memory occupied by the deleted entry. h[len(h)-1] = nil *lah = h[:len(h)-1] return e }