mirror of
https://github.com/VictoriaMetrics/VictoriaMetrics.git
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d52fd73f18
This should smooth CPU and RAM usage spikes related to these periodic tasks, by reducing the probability that multiple concurrent periodic tasks are performed at the same time.
329 lines
7.1 KiB
Go
329 lines
7.1 KiB
Go
package lrucache
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import (
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"container/heap"
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"sync"
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"sync/atomic"
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"time"
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"github.com/VictoriaMetrics/VictoriaMetrics/lib/bytesutil"
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"github.com/VictoriaMetrics/VictoriaMetrics/lib/cgroup"
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"github.com/VictoriaMetrics/VictoriaMetrics/lib/fasttime"
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"github.com/VictoriaMetrics/VictoriaMetrics/lib/timeutil"
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"github.com/cespare/xxhash/v2"
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)
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// Cache caches Entry entries.
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//
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// Call NewCache() for creating new Cache.
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type Cache struct {
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shards []*cache
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cleanerMustStopCh chan struct{}
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cleanerStoppedCh chan struct{}
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}
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// NewCache creates new cache.
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//
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// Cache size in bytes is limited by the value returned by getMaxSizeBytes() callback.
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// Call MustStop() in order to free up resources occupied by Cache.
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func NewCache(getMaxSizeBytes func() int) *Cache {
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cpusCount := cgroup.AvailableCPUs()
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shardsCount := cgroup.AvailableCPUs()
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// Increase the number of shards with the increased number of available CPU cores.
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// This should reduce contention on per-shard mutexes.
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multiplier := cpusCount
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if multiplier > 16 {
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multiplier = 16
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}
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shardsCount *= multiplier
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shards := make([]*cache, shardsCount)
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getMaxShardBytes := func() int {
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n := getMaxSizeBytes()
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return n / shardsCount
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}
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for i := range shards {
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shards[i] = newCache(getMaxShardBytes)
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}
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c := &Cache{
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shards: shards,
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cleanerMustStopCh: make(chan struct{}),
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cleanerStoppedCh: make(chan struct{}),
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}
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go c.cleaner()
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return c
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}
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// MustStop frees up resources occupied by c.
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func (c *Cache) MustStop() {
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close(c.cleanerMustStopCh)
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<-c.cleanerStoppedCh
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}
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// GetEntry returns an Entry for the given key k from c.
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func (c *Cache) GetEntry(k string) Entry {
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idx := uint64(0)
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if len(c.shards) > 1 {
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h := hashUint64(k)
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idx = h % uint64(len(c.shards))
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}
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shard := c.shards[idx]
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return shard.GetEntry(k)
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}
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// PutEntry puts the given Entry e under the given key k into c.
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func (c *Cache) PutEntry(k string, e Entry) {
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idx := uint64(0)
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if len(c.shards) > 1 {
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h := hashUint64(k)
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idx = h % uint64(len(c.shards))
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}
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shard := c.shards[idx]
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shard.PutEntry(k, e)
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}
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// Len returns the number of blocks in the cache c.
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func (c *Cache) Len() int {
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n := 0
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for _, shard := range c.shards {
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n += shard.Len()
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}
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return n
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}
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// SizeBytes returns an approximate size in bytes of all the blocks stored in the cache c.
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func (c *Cache) SizeBytes() int {
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n := 0
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for _, shard := range c.shards {
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n += shard.SizeBytes()
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}
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return n
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}
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// SizeMaxBytes returns the max allowed size in bytes for c.
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func (c *Cache) SizeMaxBytes() int {
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n := 0
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for _, shard := range c.shards {
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n += shard.SizeMaxBytes()
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}
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return n
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}
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// Requests returns the number of requests served by c.
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func (c *Cache) Requests() uint64 {
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n := uint64(0)
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for _, shard := range c.shards {
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n += shard.Requests()
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}
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return n
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}
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// Misses returns the number of cache misses for c.
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func (c *Cache) Misses() uint64 {
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n := uint64(0)
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for _, shard := range c.shards {
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n += shard.Misses()
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}
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return n
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}
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func (c *Cache) cleaner() {
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d := timeutil.AddJitterToDuration(time.Second * 53)
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ticker := time.NewTicker(d)
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defer ticker.Stop()
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for {
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select {
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case <-c.cleanerMustStopCh:
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close(c.cleanerStoppedCh)
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return
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case <-ticker.C:
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c.cleanByTimeout()
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}
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}
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}
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func (c *Cache) cleanByTimeout() {
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for _, shard := range c.shards {
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shard.cleanByTimeout()
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}
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}
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type cache struct {
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// Atomically updated fields must go first in the struct, so they are properly
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// aligned to 8 bytes on 32-bit architectures.
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// See https://github.com/VictoriaMetrics/VictoriaMetrics/issues/212
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requests uint64
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misses uint64
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// sizeBytes contains an approximate size for all the blocks stored in the cache.
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sizeBytes int64
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// getMaxSizeBytes() is a callback, which returns the maximum allowed cache size in bytes.
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getMaxSizeBytes func() int
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// mu protects all the fields below.
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mu sync.Mutex
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// m contains cached entries
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m map[string]*cacheEntry
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// The heap for removing the least recently used entries from m.
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lah lastAccessHeap
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}
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func hashUint64(s string) uint64 {
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b := bytesutil.ToUnsafeBytes(s)
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return xxhash.Sum64(b)
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}
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// Entry is an item, which may be cached in the Cache.
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type Entry interface {
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// SizeBytes must return the approximate size of the given entry in bytes
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SizeBytes() int
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}
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type cacheEntry struct {
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// The timestamp in seconds for the last access to the given entry.
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lastAccessTime uint64
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// heapIdx is the index for the entry in lastAccessHeap.
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heapIdx int
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// k contains the associated key for the given entry.
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k string
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// e contains the cached entry.
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e Entry
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}
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func newCache(getMaxSizeBytes func() int) *cache {
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var c cache
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c.getMaxSizeBytes = getMaxSizeBytes
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c.m = make(map[string]*cacheEntry)
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return &c
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}
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func (c *cache) updateSizeBytes(n int) {
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atomic.AddInt64(&c.sizeBytes, int64(n))
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}
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func (c *cache) cleanByTimeout() {
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// Delete items accessed more than three minutes ago.
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// This time should be enough for repeated queries.
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lastAccessTime := fasttime.UnixTimestamp() - 3*60
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c.mu.Lock()
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defer c.mu.Unlock()
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for len(c.lah) > 0 {
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if lastAccessTime < c.lah[0].lastAccessTime {
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break
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}
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c.removeLeastRecentlyAccessedItem()
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}
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}
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func (c *cache) GetEntry(k string) Entry {
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atomic.AddUint64(&c.requests, 1)
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c.mu.Lock()
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defer c.mu.Unlock()
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ce := c.m[k]
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if ce == nil {
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atomic.AddUint64(&c.misses, 1)
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return nil
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}
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currentTime := fasttime.UnixTimestamp()
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if ce.lastAccessTime != currentTime {
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ce.lastAccessTime = currentTime
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heap.Fix(&c.lah, ce.heapIdx)
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}
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return ce.e
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}
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func (c *cache) PutEntry(k string, e Entry) {
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c.mu.Lock()
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defer c.mu.Unlock()
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ce := c.m[k]
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if ce != nil {
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// The entry has been already registered by concurrent goroutine.
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return
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}
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ce = &cacheEntry{
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lastAccessTime: fasttime.UnixTimestamp(),
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k: k,
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e: e,
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}
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heap.Push(&c.lah, ce)
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c.m[k] = ce
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c.updateSizeBytes(e.SizeBytes())
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maxSizeBytes := c.getMaxSizeBytes()
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for c.SizeBytes() > maxSizeBytes && len(c.lah) > 0 {
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c.removeLeastRecentlyAccessedItem()
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}
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}
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func (c *cache) removeLeastRecentlyAccessedItem() {
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ce := c.lah[0]
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c.updateSizeBytes(-ce.e.SizeBytes())
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delete(c.m, ce.k)
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heap.Pop(&c.lah)
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}
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func (c *cache) Len() int {
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c.mu.Lock()
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defer c.mu.Unlock()
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return len(c.m)
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}
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func (c *cache) SizeBytes() int {
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return int(atomic.LoadInt64(&c.sizeBytes))
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}
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func (c *cache) SizeMaxBytes() int {
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return c.getMaxSizeBytes()
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}
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func (c *cache) Requests() uint64 {
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return atomic.LoadUint64(&c.requests)
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}
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func (c *cache) Misses() uint64 {
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return atomic.LoadUint64(&c.misses)
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}
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// lastAccessHeap implements heap.Interface
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type lastAccessHeap []*cacheEntry
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func (lah *lastAccessHeap) Len() int {
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return len(*lah)
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}
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func (lah *lastAccessHeap) Swap(i, j int) {
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h := *lah
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a := h[i]
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b := h[j]
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a.heapIdx = j
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b.heapIdx = i
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h[i] = b
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h[j] = a
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}
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func (lah *lastAccessHeap) Less(i, j int) bool {
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h := *lah
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return h[i].lastAccessTime < h[j].lastAccessTime
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}
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func (lah *lastAccessHeap) Push(x interface{}) {
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e := x.(*cacheEntry)
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h := *lah
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e.heapIdx = len(h)
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*lah = append(h, e)
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}
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func (lah *lastAccessHeap) Pop() interface{} {
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h := *lah
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e := h[len(h)-1]
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// Remove the reference to deleted entry, so Go GC could free up memory occupied by the deleted entry.
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h[len(h)-1] = nil
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*lah = h[:len(h)-1]
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return e
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}
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