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cache.go
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cache.go
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package rueidis
import (
"context"
"sync"
"time"
)
// NewCacheStoreFn can be provided in ClientOption for using a custom CacheStore implementation
type NewCacheStoreFn func(CacheStoreOption) CacheStore
// CacheStoreOption will be passed to NewCacheStoreFn
type CacheStoreOption struct {
// CacheSizeEachConn is redis client side cache size that bind to each TCP connection to a single redis instance.
// The default is DefaultCacheBytes.
CacheSizeEachConn int
}
// CacheStore is the store interface for the client side caching
// More detailed interface requirement can be found in cache_test.go
type CacheStore interface {
// Flight is called when DoCache and DoMultiCache, with the requested client side ttl and the current time.
// It should look up the store in single-flight manner and return one of the following three combinations:
// Case 1: (empty RedisMessage, nil CacheEntry) <- when cache missed, and rueidis will send the request to redis.
// Case 2: (empty RedisMessage, non-nil CacheEntry) <- when cache missed, and rueidis will use CacheEntry.Wait to wait for response.
// Case 3: (non-empty RedisMessage, nil CacheEntry) <- when cache hit
Flight(key, cmd string, ttl time.Duration, now time.Time) (v RedisMessage, e CacheEntry)
// Update is called when receiving the response of the request sent by the above Flight Case 1 from redis.
// It should not only update the store but also deliver the response to all CacheEntry.Wait and return a desired client side PXAT of the response.
// Note that the server side expire time can be retrieved from RedisMessage.CachePXAT.
Update(key, cmd string, val RedisMessage) (pxat int64)
// Cancel is called when the request sent by the above Flight Case 1 failed.
// It should not only deliver the error to all CacheEntry.Wait but also remove the CacheEntry from the store.
Cancel(key, cmd string, err error)
// Delete is called when receiving invalidation notifications from redis.
// If the keys is nil then it should delete all non-pending cached entries under all keys.
// If the keys is not nil then it should delete all non-pending cached entries under those keys.
Delete(keys []RedisMessage)
// Close is called when connection between redis is broken.
// It should flush all cached entries and deliver the error to all pending CacheEntry.Wait.
Close(err error)
}
// CacheEntry should be used to wait for single-flight response when cache missed.
type CacheEntry interface {
Wait(ctx context.Context) (RedisMessage, error)
}
// SimpleCache is an alternative interface should be paired with NewSimpleCacheAdapter to construct a CacheStore
type SimpleCache interface {
Get(key string) RedisMessage
Set(key string, val RedisMessage)
Del(key string)
Flush()
}
// NewSimpleCacheAdapter converts a SimpleCache into CacheStore
func NewSimpleCacheAdapter(store SimpleCache) CacheStore {
return &adapter{store: store, flights: make(map[string]map[string]CacheEntry)}
}
type adapter struct {
store SimpleCache
flights map[string]map[string]CacheEntry
mu sync.RWMutex
}
func (a *adapter) Flight(key, cmd string, ttl time.Duration, now time.Time) (RedisMessage, CacheEntry) {
a.mu.RLock()
if v := a.store.Get(key + cmd); v.typ != 0 && v.relativePTTL(now) > 0 {
a.mu.RUnlock()
return v, nil
}
flight := a.flights[key][cmd]
a.mu.RUnlock()
if flight != nil {
return RedisMessage{}, flight
}
a.mu.Lock()
entries := a.flights[key]
if entries == nil && a.flights != nil {
entries = make(map[string]CacheEntry, 1)
a.flights[key] = entries
}
if flight = entries[cmd]; flight == nil && entries != nil {
entries[cmd] = &adapterEntry{ch: make(chan struct{}), xat: now.Add(ttl).UnixMilli()}
}
a.mu.Unlock()
return RedisMessage{}, flight
}
func (a *adapter) Update(key, cmd string, val RedisMessage) (sxat int64) {
a.mu.Lock()
entries := a.flights[key]
if flight, ok := entries[cmd].(*adapterEntry); ok {
sxat = val.getExpireAt()
if flight.xat < sxat || sxat == 0 {
sxat = flight.xat
val.setExpireAt(sxat)
}
a.store.Set(key+cmd, val)
flight.set(val, nil)
entries[cmd] = nil
}
a.mu.Unlock()
return
}
func (a *adapter) Cancel(key, cmd string, err error) {
a.mu.Lock()
entries := a.flights[key]
if flight, ok := entries[cmd].(*adapterEntry); ok {
flight.set(RedisMessage{}, err)
entries[cmd] = nil
}
a.mu.Unlock()
}
func (a *adapter) del(key string) {
entries := a.flights[key]
for cmd, e := range entries {
if e == nil {
a.store.Del(key + cmd)
delete(entries, cmd)
}
}
if len(entries) == 0 {
delete(a.flights, key)
}
}
func (a *adapter) Delete(keys []RedisMessage) {
a.mu.Lock()
if keys == nil {
for key := range a.flights {
a.del(key)
}
} else {
for _, k := range keys {
a.del(k.string)
}
}
a.mu.Unlock()
}
func (a *adapter) Close(err error) {
a.mu.Lock()
flights := a.flights
a.flights = nil
a.store.Flush()
a.mu.Unlock()
for _, entries := range flights {
for _, e := range entries {
if e != nil {
e.(*adapterEntry).set(RedisMessage{}, err)
}
}
}
}
type adapterEntry struct {
err error
ch chan struct{}
val RedisMessage
xat int64
}
func (a *adapterEntry) set(val RedisMessage, err error) {
a.err, a.val = err, val
close(a.ch)
}
func (a *adapterEntry) Wait(ctx context.Context) (RedisMessage, error) {
select {
case <-ctx.Done():
return RedisMessage{}, ctx.Err()
case <-a.ch:
return a.val, a.err
}
}