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.
452 lines
12 KiB
Go
452 lines
12 KiB
Go
package workingsetcache
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import (
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"flag"
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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/timeutil"
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"github.com/VictoriaMetrics/fastcache"
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)
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var (
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prevCacheRemovalPercent = flag.Float64("prevCacheRemovalPercent", 0.1, "Items in the previous caches are removed when the percent of requests it serves "+
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"becomes lower than this value. Higher values reduce memory usage at the cost of higher CPU usage. See also -cacheExpireDuration")
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cacheExpireDuration = flag.Duration("cacheExpireDuration", 30*time.Minute, "Items are removed from in-memory caches after they aren't accessed for this duration. "+
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"Lower values may reduce memory usage at the cost of higher CPU usage. See also -prevCacheRemovalPercent")
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)
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// Cache modes.
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const (
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split = 0
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switching = 1
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whole = 2
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)
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// Cache is a cache for working set entries.
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//
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// The cache evicts inactive entries after the given expireDuration.
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// Recently accessed entries survive expireDuration.
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type Cache struct {
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curr atomic.Pointer[fastcache.Cache]
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prev atomic.Pointer[fastcache.Cache]
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// csHistory holds cache stats history
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csHistory fastcache.Stats
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// mode indicates whether to use only curr and skip prev.
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//
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// This flag is set to switching if curr is filled for more than 50% space.
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// In this case using prev would result in RAM waste,
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// it is better to use only curr cache with doubled size.
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// After the process of switching, this flag will be set to whole.
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mode uint32
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// The maxBytes value passed to New() or to Load().
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maxBytes int
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// mu serializes access to curr, prev and mode
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// in expirationWatcher, prevCacheWatcher and cacheSizeWatcher.
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mu sync.Mutex
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wg sync.WaitGroup
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stopCh chan struct{}
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}
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// Load loads the cache from filePath and limits its size to maxBytes
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// and evicts inactive entries in *cacheExpireDuration minutes.
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//
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// Stop must be called on the returned cache when it is no longer needed.
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func Load(filePath string, maxBytes int) *Cache {
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return loadWithExpire(filePath, maxBytes, *cacheExpireDuration)
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}
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func loadWithExpire(filePath string, maxBytes int, expireDuration time.Duration) *Cache {
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curr := fastcache.LoadFromFileOrNew(filePath, maxBytes)
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var cs fastcache.Stats
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curr.UpdateStats(&cs)
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if cs.EntriesCount == 0 {
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curr.Reset()
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// The cache couldn't be loaded with maxBytes size.
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// This may mean that the cache is split into curr and prev caches.
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// Try loading it again with maxBytes / 2 size.
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// Put the loaded cache into `prev` instead of `curr`
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// in order to limit the growth of the cache for the current period of time.
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prev := fastcache.LoadFromFileOrNew(filePath, maxBytes/2)
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curr := fastcache.New(maxBytes / 2)
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c := newCacheInternal(curr, prev, split, maxBytes)
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c.runWatchers(expireDuration)
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return c
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}
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// The cache has been successfully loaded in full.
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// Set its' mode to `whole`.
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// There is no need in runWatchers call.
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prev := fastcache.New(1024)
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return newCacheInternal(curr, prev, whole, maxBytes)
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}
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// New creates new cache with the given maxBytes capacity and *cacheExpireDuration expiration.
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//
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// Stop must be called on the returned cache when it is no longer needed.
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func New(maxBytes int) *Cache {
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return newWithExpire(maxBytes, *cacheExpireDuration)
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}
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func newWithExpire(maxBytes int, expireDuration time.Duration) *Cache {
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curr := fastcache.New(maxBytes / 2)
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prev := fastcache.New(1024)
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c := newCacheInternal(curr, prev, split, maxBytes)
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c.runWatchers(expireDuration)
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return c
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}
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func newCacheInternal(curr, prev *fastcache.Cache, mode, maxBytes int) *Cache {
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var c Cache
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c.maxBytes = maxBytes
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c.curr.Store(curr)
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c.prev.Store(prev)
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c.stopCh = make(chan struct{})
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c.setMode(mode)
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return &c
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}
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func (c *Cache) runWatchers(expireDuration time.Duration) {
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c.wg.Add(1)
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go func() {
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defer c.wg.Done()
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c.expirationWatcher(expireDuration)
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}()
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c.wg.Add(1)
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go func() {
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defer c.wg.Done()
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c.prevCacheWatcher()
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}()
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c.wg.Add(1)
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go func() {
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defer c.wg.Done()
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c.cacheSizeWatcher()
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}()
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}
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func (c *Cache) expirationWatcher(expireDuration time.Duration) {
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expireDuration = timeutil.AddJitterToDuration(expireDuration)
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t := time.NewTicker(expireDuration)
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defer t.Stop()
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for {
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select {
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case <-c.stopCh:
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return
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case <-t.C:
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}
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c.mu.Lock()
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if atomic.LoadUint32(&c.mode) != split {
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// Stop the expirationWatcher on non-split mode.
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c.mu.Unlock()
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return
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}
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// Reset prev cache and swap it with the curr cache.
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prev := c.prev.Load()
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curr := c.curr.Load()
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c.prev.Store(curr)
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var cs fastcache.Stats
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prev.UpdateStats(&cs)
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updateCacheStatsHistory(&c.csHistory, &cs)
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prev.Reset()
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c.curr.Store(prev)
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c.mu.Unlock()
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}
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}
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func (c *Cache) prevCacheWatcher() {
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p := *prevCacheRemovalPercent / 100
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if p <= 0 {
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// There is no need in removing the previous cache.
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return
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}
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minCurrRequests := uint64(1 / p)
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// Watch for the usage of the prev cache and drop it whenever it receives
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// less than prevCacheRemovalPercent requests comparing to the curr cache during the last 60 seconds.
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checkInterval := timeutil.AddJitterToDuration(time.Second * 60)
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t := time.NewTicker(checkInterval)
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defer t.Stop()
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prevGetCalls := uint64(0)
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currGetCalls := uint64(0)
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for {
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select {
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case <-c.stopCh:
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return
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case <-t.C:
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}
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c.mu.Lock()
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if atomic.LoadUint32(&c.mode) != split {
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// Do nothing in non-split mode.
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c.mu.Unlock()
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return
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}
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prev := c.prev.Load()
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curr := c.curr.Load()
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var csCurr, csPrev fastcache.Stats
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curr.UpdateStats(&csCurr)
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prev.UpdateStats(&csPrev)
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currRequests := csCurr.GetCalls
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if currRequests >= currGetCalls {
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currRequests -= currGetCalls
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}
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prevRequests := csPrev.GetCalls
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if prevRequests >= prevGetCalls {
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prevRequests -= prevGetCalls
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}
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currGetCalls = csCurr.GetCalls
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prevGetCalls = csPrev.GetCalls
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if currRequests >= minCurrRequests && float64(prevRequests)/float64(currRequests) < p {
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// The majority of requests are served from the curr cache,
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// so the prev cache can be deleted in order to free up memory.
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if csPrev.EntriesCount > 0 {
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updateCacheStatsHistory(&c.csHistory, &csPrev)
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prev.Reset()
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}
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}
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c.mu.Unlock()
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}
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}
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func (c *Cache) cacheSizeWatcher() {
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checkInterval := timeutil.AddJitterToDuration(time.Millisecond * 1500)
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t := time.NewTicker(checkInterval)
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defer t.Stop()
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var maxBytesSize uint64
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for {
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select {
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case <-c.stopCh:
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return
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case <-t.C:
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}
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if c.loadMode() != split {
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continue
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}
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var cs fastcache.Stats
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curr := c.curr.Load()
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curr.UpdateStats(&cs)
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if cs.BytesSize >= uint64(0.9*float64(cs.MaxBytesSize)) {
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maxBytesSize = cs.MaxBytesSize
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break
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}
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}
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// curr cache size exceeds 90% of its capacity. It is better
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// to double the size of curr cache and stop using prev cache,
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// since this will result in higher summary cache capacity.
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//
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// Do this in the following steps:
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// 1) switch to mode=switching
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// 2) move curr cache to prev
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// 3) create curr cache with doubled size
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// 4) wait until curr cache size exceeds maxBytesSize, i.e. it is populated with new data
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// 5) switch to mode=whole
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// 6) drop prev cache
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c.mu.Lock()
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c.setMode(switching)
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prev := c.prev.Load()
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curr := c.curr.Load()
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c.prev.Store(curr)
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var cs fastcache.Stats
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prev.UpdateStats(&cs)
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updateCacheStatsHistory(&c.csHistory, &cs)
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prev.Reset()
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// use c.maxBytes instead of maxBytesSize*2 for creating new cache, since otherwise the created cache
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// couldn't be loaded from file with c.maxBytes limit after saving with maxBytesSize*2 limit.
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c.curr.Store(fastcache.New(c.maxBytes))
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c.mu.Unlock()
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for {
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select {
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case <-c.stopCh:
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return
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case <-t.C:
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}
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var cs fastcache.Stats
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curr := c.curr.Load()
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curr.UpdateStats(&cs)
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if cs.BytesSize >= maxBytesSize {
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break
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}
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}
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c.mu.Lock()
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c.setMode(whole)
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prev = c.prev.Load()
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c.prev.Store(fastcache.New(1024))
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cs.Reset()
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prev.UpdateStats(&cs)
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updateCacheStatsHistory(&c.csHistory, &cs)
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prev.Reset()
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c.mu.Unlock()
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}
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// Save saves the cache to filePath.
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func (c *Cache) Save(filePath string) error {
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curr := c.curr.Load()
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concurrency := cgroup.AvailableCPUs()
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return curr.SaveToFileConcurrent(filePath, concurrency)
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}
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// Stop stops the cache.
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//
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// The cache cannot be used after the Stop call.
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func (c *Cache) Stop() {
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close(c.stopCh)
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c.wg.Wait()
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c.Reset()
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}
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// Reset resets the cache.
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func (c *Cache) Reset() {
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var cs fastcache.Stats
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prev := c.prev.Load()
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prev.UpdateStats(&cs)
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prev.Reset()
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curr := c.curr.Load()
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curr.UpdateStats(&cs)
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updateCacheStatsHistory(&c.csHistory, &cs)
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curr.Reset()
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// Reset the mode to `split` in the hope the working set size becomes smaller after the reset.
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c.setMode(split)
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}
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func (c *Cache) setMode(mode int) {
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atomic.StoreUint32(&c.mode, uint32(mode))
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}
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func (c *Cache) loadMode() int {
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return int(atomic.LoadUint32(&c.mode))
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}
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// UpdateStats updates fcs with cache stats.
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func (c *Cache) UpdateStats(fcs *fastcache.Stats) {
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updateCacheStatsHistory(fcs, &c.csHistory)
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var cs fastcache.Stats
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curr := c.curr.Load()
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curr.UpdateStats(&cs)
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updateCacheStats(fcs, &cs)
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prev := c.prev.Load()
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cs.Reset()
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prev.UpdateStats(&cs)
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updateCacheStats(fcs, &cs)
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}
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func updateCacheStats(dst, src *fastcache.Stats) {
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dst.GetCalls += src.GetCalls
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dst.SetCalls += src.SetCalls
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dst.Misses += src.Misses
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dst.Collisions += src.Collisions
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dst.Corruptions += src.Corruptions
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dst.EntriesCount += src.EntriesCount
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dst.BytesSize += src.BytesSize
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dst.MaxBytesSize += src.MaxBytesSize
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}
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func updateCacheStatsHistory(dst, src *fastcache.Stats) {
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atomic.AddUint64(&dst.GetCalls, atomic.LoadUint64(&src.GetCalls))
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atomic.AddUint64(&dst.SetCalls, atomic.LoadUint64(&src.SetCalls))
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atomic.AddUint64(&dst.Misses, atomic.LoadUint64(&src.Misses))
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atomic.AddUint64(&dst.Collisions, atomic.LoadUint64(&src.Collisions))
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atomic.AddUint64(&dst.Corruptions, atomic.LoadUint64(&src.Corruptions))
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// Do not add EntriesCount, BytesSize and MaxBytesSize, since these metrics
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// are calculated from c.curr and c.prev caches.
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}
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// Get appends the found value for the given key to dst and returns the result.
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func (c *Cache) Get(dst, key []byte) []byte {
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curr := c.curr.Load()
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result := curr.Get(dst, key)
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if len(result) > len(dst) {
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// Fast path - the entry is found in the current cache.
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return result
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}
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if c.loadMode() == whole {
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// Nothing found.
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return result
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}
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// Search for the entry in the previous cache.
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prev := c.prev.Load()
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result = prev.Get(dst, key)
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if len(result) <= len(dst) {
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// Nothing found.
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return result
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}
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// Cache the found entry in the current cache.
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curr.Set(key, result[len(dst):])
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return result
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}
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// Has verifies whether the cache contains the given key.
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func (c *Cache) Has(key []byte) bool {
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curr := c.curr.Load()
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if curr.Has(key) {
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return true
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}
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if c.loadMode() == whole {
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return false
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}
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prev := c.prev.Load()
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if !prev.Has(key) {
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return false
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}
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// Cache the found entry in the current cache.
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tmpBuf := tmpBufPool.Get()
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tmpBuf.B = prev.Get(tmpBuf.B, key)
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curr.Set(key, tmpBuf.B)
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tmpBufPool.Put(tmpBuf)
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return true
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}
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var tmpBufPool bytesutil.ByteBufferPool
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// Set sets the given value for the given key.
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func (c *Cache) Set(key, value []byte) {
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curr := c.curr.Load()
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curr.Set(key, value)
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}
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// GetBig appends the found value for the given key to dst and returns the result.
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func (c *Cache) GetBig(dst, key []byte) []byte {
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curr := c.curr.Load()
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result := curr.GetBig(dst, key)
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if len(result) > len(dst) {
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// Fast path - the entry is found in the current cache.
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return result
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}
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if c.loadMode() == whole {
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// Nothing found.
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return result
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}
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// Search for the entry in the previous cache.
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prev := c.prev.Load()
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result = prev.GetBig(dst, key)
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if len(result) <= len(dst) {
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// Nothing found.
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return result
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}
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// Cache the found entry in the current cache.
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curr.SetBig(key, result[len(dst):])
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return result
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}
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// SetBig sets the given value for the given key.
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func (c *Cache) SetBig(key, value []byte) {
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curr := c.curr.Load()
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curr.SetBig(key, value)
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}
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