go-cache/cache.go

560 lines
14 KiB
Go

package cache
import (
"encoding/gob"
"fmt"
"io"
"os"
"runtime"
"sync"
"time"
)
type Item [T comparable] struct {
Object T
Expiration int64
}
// Returns true if the item has expired.
func (item Item[T]) Expired() bool {
if item.Expiration == 0 {
return false
}
return time.Now().UnixNano() > item.Expiration
}
const (
// For use with functions that take an expiration time.
NoExpiration time.Duration = -1
// For use with functions that take an expiration time. Equivalent to
// passing in the same expiration duration as was given to New() or
// NewFrom() when the cache was created (e.g. 5 minutes.)
DefaultExpiration time.Duration = 0
)
type Cache [T comparable] struct {
*cache[T]
// If this is confusing, see the comment at the bottom of New()
}
type cache [T comparable] struct {
defaultExpiration time.Duration
items map[string]Item[T]
mu sync.RWMutex
onEvicted func(string, T)
janitor *janitor
}
// Add an item to the cache, replacing any existing item. If the duration is 0
// (DefaultExpiration), the cache's default expiration time is used. If it is -1
// (NoExpiration), the item never expires.
func (c *cache[T]) Set(k string, x T, d time.Duration) {
// "Inlining" of set
var e int64
if d == DefaultExpiration {
d = c.defaultExpiration
}
if d > 0 {
e = time.Now().Add(d).UnixNano()
}
c.mu.Lock()
c.items[k] = Item[T]{
Object: x,
Expiration: e,
}
// TODO: Calls to mu.Unlock are currently not deferred because defer
// adds ~200 ns (as of go1.)
c.mu.Unlock()
}
func (c *cache[T]) set(k string, x T, d time.Duration) {
var e int64
if d == DefaultExpiration {
d = c.defaultExpiration
}
if d > 0 {
e = time.Now().Add(d).UnixNano()
}
c.items[k] = Item[T]{
Object: x,
Expiration: e,
}
}
// Add an item to the cache, replacing any existing item, using the default
// expiration.
func (c *cache[T]) SetDefault(k string, x T) {
c.Set(k, x, DefaultExpiration)
}
// Add an item to the cache only if an item doesn't already exist for the given
// key, or if the existing item has expired. Returns an error otherwise.
func (c *cache[T]) Add(k string, x T, d time.Duration) error {
c.mu.Lock()
_, found := c.get(k)
if found {
c.mu.Unlock()
return fmt.Errorf("Item %s already exists", k)
}
c.set(k, x, d)
c.mu.Unlock()
return nil
}
// Set a new value for the cache key only if it already exists, and the existing
// item hasn't expired. Returns an error otherwise.
func (c *cache[T]) Replace(k string, x T, d time.Duration) error {
c.mu.Lock()
_, found := c.get(k)
if !found {
c.mu.Unlock()
return fmt.Errorf("Item %s doesn't exist", k)
}
c.set(k, x, d)
c.mu.Unlock()
return nil
}
// Get an item from the cache. Returns the item or nil, and a bool indicating
// whether the key was found.
func (c *cache[T]) Get(k string) (T, bool) {
c.mu.RLock()
var zero T
// "Inlining" of get and Expired
item, found := c.items[k]
if !found {
c.mu.RUnlock()
return zero, false
}
if item.Expiration > 0 {
if time.Now().UnixNano() > item.Expiration {
c.mu.RUnlock()
return zero, false
}
}
c.mu.RUnlock()
return item.Object, true
}
// GetWithExpiration returns an item and its expiration time from the cache.
// It returns the item or nil, the expiration time if one is set (if the item
// never expires a zero value for time.Time is returned), and a bool indicating
// whether the key was found.
func (c *cache[T]) GetWithExpiration(k string) (T, time.Time, bool) {
c.mu.RLock()
var zero T
// "Inlining" of get and Expired
item, found := c.items[k]
if !found {
c.mu.RUnlock()
return zero, time.Time{}, false
}
if item.Expiration > 0 {
if time.Now().UnixNano() > item.Expiration {
c.mu.RUnlock()
return zero, time.Time{}, false
}
// Return the item and the expiration time
c.mu.RUnlock()
return item.Object, time.Unix(0, item.Expiration), true
}
// If expiration <= 0 (i.e. no expiration time set) then return the item
// and a zeroed time.Time
c.mu.RUnlock()
return item.Object, time.Time{}, true
}
func (c *cache[T]) get(k string) (T, bool) {
item, found := c.items[k]
var zero T
if !found {
return zero, false
}
// "Inlining" of Expired
if item.Expiration > 0 {
if time.Now().UnixNano() > item.Expiration {
return zero, false
}
}
return item.Object, true
}
type Incrementable interface {
~int | ~int8 | ~int16 | ~int32 | ~int64 | ~uintptr | ~uint | ~uint8 | ~uint32 | ~uint64 | ~float32 | ~float64
}
// Can't decrement unsigned values
type Decrementable interface {
~int | ~int8 | ~int16 | ~int32 | ~int64 | ~float32 | ~float64
}
func (c *cache[T]) Increment(k string, n int64) (T, error) {
c.mu.Lock()
var zero T
v, found := c.items[k]
if !found || v.Expired() {
c.mu.Unlock()
return zero, fmt.Errorf("Item %s not found", k)
}
// Generics does not (currently?) support type switching
// To workaround, we convert the value into a interface{}, and switching on that
var untypedValue interface{}
untypedValue = v.Object
switch untypedValue.(type) {
case int:
untypedValue = untypedValue.(int) + int(n)
case int8:
untypedValue = untypedValue.(int8) + int8(n)
case int16:
untypedValue = untypedValue.(int16) + int16(n)
case int32:
untypedValue= untypedValue.(int32) + int32(n)
case int64:
untypedValue = untypedValue.(int64) + n
case uint:
untypedValue = untypedValue.(uint) + uint(n)
case uintptr:
untypedValue = untypedValue.(uintptr) + uintptr(n)
case uint8:
untypedValue = untypedValue.(uint8) + uint8(n)
case uint16:
untypedValue = untypedValue.(uint16) + uint16(n)
case uint32:
untypedValue = untypedValue.(uint32) + uint32(n)
case uint64:
untypedValue = untypedValue.(uint64) + uint64(n)
case float32:
untypedValue = untypedValue.(float32) + float32(n)
case float64:
untypedValue = untypedValue.(float64) + float64(n)
default:
c.mu.Unlock()
return zero, fmt.Errorf("The value for %s is not an integer", k)
}
v.Object = untypedValue.(T)
c.items[k] = v
c.mu.Unlock()
return zero, nil
}
func (c *cache[T]) Decrement(k string, n int64) (T, error) {
c.mu.Lock()
var zero T
v, found := c.items[k]
if !found || v.Expired() {
c.mu.Unlock()
return zero, fmt.Errorf("Item %s not found", k)
}
// Generics does not (currently?) support type switching
// To workaround, we convert the value into a interface{}, and switching on that
var untypedValue interface{}
untypedValue = v.Object
switch untypedValue.(type) {
case int:
untypedValue = untypedValue.(int) - int(n)
case int8:
untypedValue = untypedValue.(int8) - int8(n)
case int16:
untypedValue = untypedValue.(int16) - int16(n)
case int32:
untypedValue= untypedValue.(int32) - int32(n)
case int64:
untypedValue = untypedValue.(int64) - n
case uint:
untypedValue = untypedValue.(uint) - uint(n)
case uintptr:
untypedValue = untypedValue.(uintptr) - uintptr(n)
case uint8:
untypedValue = untypedValue.(uint8) - uint8(n)
case uint16:
untypedValue = untypedValue.(uint16) - uint16(n)
case uint32:
untypedValue = untypedValue.(uint32) - uint32(n)
case uint64:
untypedValue = untypedValue.(uint64) - uint64(n)
case float32:
untypedValue = untypedValue.(float32) - float32(n)
case float64:
untypedValue = untypedValue.(float64) - float64(n)
default:
c.mu.Unlock()
return zero, fmt.Errorf("The value for %s is not an integer", k)
}
v.Object = untypedValue.(T)
c.items[k] = v
c.mu.Unlock()
return zero, nil
}
// Delete an item from the cache. Does nothing if the key is not in the cache.
func (c *cache[T]) Delete(k string) {
c.mu.Lock()
v, evicted := c.delete(k)
c.mu.Unlock()
if evicted {
c.onEvicted(k, v)
}
}
func (c *cache[T]) delete(k string) (T, bool) {
var zero T
if c.onEvicted != nil {
if v, found := c.items[k]; found {
delete(c.items, k)
return v.Object, true
}
}
delete(c.items, k)
return zero, false
}
type keyAndValue[T comparable] struct {
key string
value T
}
// Delete all expired items from the cache.
func (c *cache[T]) DeleteExpired() {
var evictedItems []keyAndValue[T]
now := time.Now().UnixNano()
c.mu.Lock()
for k, v := range c.items {
// "Inlining" of expired
if v.Expiration > 0 && now > v.Expiration {
ov, evicted := c.delete(k)
if evicted {
evictedItems = append(evictedItems, keyAndValue[T]{k, ov})
}
}
}
c.mu.Unlock()
for _, v := range evictedItems {
c.onEvicted(v.key, v.value)
}
}
// Sets an (optional) function that is called with the key and value when an
// item is evicted from the cache. (Including when it is deleted manually, but
// not when it is overwritten.) Set to nil to disable.
func (c *cache[T]) OnEvicted(f func(string, T)) {
c.mu.Lock()
c.onEvicted = f
c.mu.Unlock()
}
// Write the cache's items (using Gob) to an io.Writer.
//
// NOTE: This method is deprecated in favor of c.Items() and NewFrom() (see the
// documentation for NewFrom().)
func (c *cache[T]) Save(w io.Writer) (err error) {
enc := gob.NewEncoder(w)
defer func() {
if x := recover(); x != nil {
err = fmt.Errorf("Error registering item types with Gob library")
}
}()
c.mu.RLock()
defer c.mu.RUnlock()
for _, v := range c.items {
gob.Register(v.Object)
}
err = enc.Encode(&c.items)
return
}
// Save the cache's items to the given filename, creating the file if it
// doesn't exist, and overwriting it if it does.
//
// NOTE: This method is deprecated in favor of c.Items() and NewFrom() (see the
// documentation for NewFrom().)
func (c *cache[T]) SaveFile(fname string) error {
fp, err := os.Create(fname)
if err != nil {
return err
}
err = c.Save(fp)
if err != nil {
fp.Close()
return err
}
return fp.Close()
}
// Add (Gob-serialized) cache items from an io.Reader, excluding any items with
// keys that already exist (and haven't expired) in the current cache.
//
// NOTE: This method is deprecated in favor of c.Items() and NewFrom() (see the
// documentation for NewFrom().)
func (c *cache[T]) Load(r io.Reader) error {
dec := gob.NewDecoder(r)
items := map[string]Item[T]{}
err := dec.Decode(&items)
if err == nil {
c.mu.Lock()
defer c.mu.Unlock()
for k, v := range items {
ov, found := c.items[k]
if !found || ov.Expired() {
c.items[k] = v
}
}
}
return err
}
// Load and add cache items from the given filename, excluding any items with
// keys that already exist in the current cache.
//
// NOTE: This method is deprecated in favor of c.Items() and NewFrom() (see the
// documentation for NewFrom().)
func (c *cache[T]) LoadFile(fname string) error {
fp, err := os.Open(fname)
if err != nil {
return err
}
err = c.Load(fp)
if err != nil {
fp.Close()
return err
}
return fp.Close()
}
// Copies all unexpired items in the cache into a new map and returns it.
func (c *cache[T]) Items() map[string]Item[T] {
c.mu.RLock()
defer c.mu.RUnlock()
m := make(map[string]Item[T], len(c.items))
now := time.Now().UnixNano()
for k, v := range c.items {
// "Inlining" of Expired
if v.Expiration > 0 {
if now > v.Expiration {
continue
}
}
m[k] = v
}
return m
}
// Returns the number of items in the cache. This may include items that have
// expired, but have not yet been cleaned up.
func (c *cache[T]) ItemCount() int {
c.mu.RLock()
n := len(c.items)
c.mu.RUnlock()
return n
}
// Delete all items from the cache.
func (c *cache[T]) Flush() {
c.mu.Lock()
c.items = map[string]Item[T]{}
c.mu.Unlock()
}
type janitor struct {
Interval time.Duration
stop chan bool
}
func runJanitor[T comparable](j *janitor, c *cache[T]) {
ticker := time.NewTicker(j.Interval)
for {
select {
case <-ticker.C:
c.DeleteExpired()
case <-j.stop:
ticker.Stop()
return
}
}
}
func stopJanitor[T comparable](c *Cache[T]) {
c.janitor.stop <- true
}
func startJanitor[T comparable](c *cache[T], ci time.Duration) {
j := &janitor{
Interval: ci,
stop: make(chan bool),
}
c.janitor = j
go runJanitor(j, c)
}
func newCache[T comparable](de time.Duration, m map[string]Item[T]) *cache[T] {
if de == 0 {
de = -1
}
c := &cache[T]{
defaultExpiration: de,
items: m,
}
return c
}
func newCacheWithJanitor[T comparable](de time.Duration, ci time.Duration, m map[string]Item[T]) *Cache[T] {
c := newCache(de, m)
// This trick ensures that the janitor goroutine (which--granted it
// was enabled--is running DeleteExpired on c forever) does not keep
// the returned C object from being garbage collected. When it is
// garbage collected, the finalizer stops the janitor goroutine, after
// which c can be collected.
C := &Cache[T]{c}
if ci > 0 {
startJanitor(c, ci)
runtime.SetFinalizer(C, stopJanitor[T])
}
return C
}
// Return a new cache with a given default expiration duration and cleanup
// interval. If the expiration duration is less than one (or NoExpiration),
// the items in the cache never expire (by default), and must be deleted
// manually. If the cleanup interval is less than one, expired items are not
// deleted from the cache before calling c.DeleteExpired().
func New[T comparable](defaultExpiration, cleanupInterval time.Duration) *Cache[T] {
items := make(map[string]Item[T])
return newCacheWithJanitor[T](defaultExpiration, cleanupInterval, items)
}
// Return a new cache with a given default expiration duration and cleanup
// interval. If the expiration duration is less than one (or NoExpiration),
// the items in the cache never expire (by default), and must be deleted
// manually. If the cleanup interval is less than one, expired items are not
// deleted from the cache before calling c.DeleteExpired().
//
// NewFrom() also accepts an items map which will serve as the underlying map
// for the cache. This is useful for starting from a deserialized cache
// (serialized using e.g. gob.Encode() on c.Items()), or passing in e.g.
// make(map[string]Item, 500) to improve startup performance when the cache
// is expected to reach a certain minimum size.
//
// Only the cache's methods synchronize access to this map, so it is not
// recommended to keep any references to the map around after creating a cache.
// If need be, the map can be accessed at a later point using c.Items() (subject
// to the same caveat.)
//
// Note regarding serialization: When using e.g. gob, make sure to
// gob.Register() the individual types stored in the cache before encoding a
// map retrieved with c.Items(), and to register those same types before
// decoding a blob containing an items map.
func NewFrom[T comparable](defaultExpiration, cleanupInterval time.Duration, items map[string]Item[T]) *Cache[T] {
return newCacheWithJanitor(defaultExpiration, cleanupInterval, items)
}