gotosocial/vendor/codeberg.org/gruf/go-cache/v2/ttl.go

package cache

import (
	"context"
	"sync"
	"time"

	"codeberg.org/gruf/go-runners"
)

// TTLCache is the underlying Cache implementation, providing both the base
// Cache interface and access to "unsafe" methods so that you may build your
// customized caches ontop of this structure.
type TTLCache[Key comparable, Value any] struct {
	cache   map[Key](*entry[Value])
	evict   Hook[Key, Value] // the evict hook is called when an item is evicted from the cache, includes manual delete
	invalid Hook[Key, Value] // the invalidate hook is called when an item's data in the cache is invalidated
	ttl     time.Duration    // ttl is the item TTL
	svc     runners.Service  // svc manages running of the cache eviction routine
	mu      sync.Mutex       // mu protects TTLCache for concurrent access
}

// Init performs Cache initialization, this MUST be called.
func (c *TTLCache[K, V]) Init() {
	c.cache = make(map[K](*entry[V]), 100)
	c.evict = emptyHook[K, V]
	c.invalid = emptyHook[K, V]
	c.ttl = time.Minute * 5
}

func (c *TTLCache[K, V]) Start(freq time.Duration) bool {
	// Nothing to start
	if freq <= 0 {
		return false
	}

	// Track state of starting
	done := make(chan struct{})
	started := false

	go func() {
		ran := c.svc.Run(func(ctx context.Context) {
			// Successfully started
			started = true
			close(done)

			// start routine
			c.run(ctx, freq)
		})

		// failed to start
		if !ran {
			close(done)
		}
	}()

	<-done
	return started
}

func (c *TTLCache[K, V]) Stop() bool {
	return c.svc.Stop()
}

func (c *TTLCache[K, V]) run(ctx context.Context, freq time.Duration) {
	t := time.NewTimer(freq)
	for {
		select {
		// we got stopped
		case <-ctx.Done():
			if !t.Stop() {
				<-t.C
			}
			return

		// next tick
		case <-t.C:
			c.sweep()
			t.Reset(freq)
		}
	}
}

// sweep attempts to evict expired items (with callback!) from cache.
func (c *TTLCache[K, V]) sweep() {
	// Lock and defer unlock (in case of hook panic)
	c.mu.Lock()
	defer c.mu.Unlock()

	// Fetch current time for TTL check
	now := time.Now()

	// Sweep the cache for old items!
	for key, item := range c.cache {
		if now.After(item.expiry) {
			c.evict(key, item.value)
			delete(c.cache, key)
		}
	}
}

// Lock locks the cache mutex.
func (c *TTLCache[K, V]) Lock() {
	c.mu.Lock()
}

// Unlock unlocks the cache mutex.
func (c *TTLCache[K, V]) Unlock() {
	c.mu.Unlock()
}

func (c *TTLCache[K, V]) SetEvictionCallback(hook Hook[K, V]) {
	// Ensure non-nil hook
	if hook == nil {
		hook = emptyHook[K, V]
	}

	// Safely set evict hook
	c.Lock()
	c.evict = hook
	c.Unlock()
}

func (c *TTLCache[K, V]) SetInvalidateCallback(hook Hook[K, V]) {
	// Ensure non-nil hook
	if hook == nil {
		hook = emptyHook[K, V]
	}

	// Safely set invalidate hook
	c.Lock()
	c.invalid = hook
	c.Unlock()
}

func (c *TTLCache[K, V]) SetTTL(ttl time.Duration, update bool) {
	// Safely update TTL
	c.Lock()
	diff := ttl - c.ttl
	c.ttl = ttl

	if update {
		// Update existing cache entries
		for _, entry := range c.cache {
			entry.expiry.Add(diff)
		}
	}

	// We're done
	c.Unlock()
}

func (c *TTLCache[K, V]) Get(key K) (V, bool) {
	c.Lock()
	value, ok := c.GetUnsafe(key)
	c.Unlock()
	return value, ok
}

// GetUnsafe is the mutex-unprotected logic for Cache.Get().
func (c *TTLCache[K, V]) GetUnsafe(key K) (V, bool) {
	item, ok := c.cache[key]
	if !ok {
		var value V
		return value, false
	}
	item.expiry = time.Now().Add(c.ttl)
	return item.value, true
}

func (c *TTLCache[K, V]) Put(key K, value V) bool {
	c.Lock()
	success := c.PutUnsafe(key, value)
	c.Unlock()
	return success
}

// PutUnsafe is the mutex-unprotected logic for Cache.Put().
func (c *TTLCache[K, V]) PutUnsafe(key K, value V) bool {
	// If already cached, return
	if _, ok := c.cache[key]; ok {
		return false
	}

	// Create new cached item
	c.cache[key] = &entry[V]{
		value:  value,
		expiry: time.Now().Add(c.ttl),
	}

	return true
}

func (c *TTLCache[K, V]) Set(key K, value V) {
	c.Lock()
	defer c.Unlock() // defer in case of hook panic
	c.SetUnsafe(key, value)
}

// SetUnsafe is the mutex-unprotected logic for Cache.Set(), it calls externally-set functions.
func (c *TTLCache[K, V]) SetUnsafe(key K, value V) {
	item, ok := c.cache[key]
	if ok {
		// call invalidate hook
		c.invalid(key, item.value)
	} else {
		// alloc new item
		item = &entry[V]{}
		c.cache[key] = item
	}

	// Update the item + expiry
	item.value = value
	item.expiry = time.Now().Add(c.ttl)
}

func (c *TTLCache[K, V]) CAS(key K, cmp V, swp V) bool {
	c.Lock()
	ok := c.CASUnsafe(key, cmp, swp)
	c.Unlock()
	return ok
}

// CASUnsafe is the mutex-unprotected logic for Cache.CAS().
func (c *TTLCache[K, V]) CASUnsafe(key K, cmp V, swp V) bool {
	// Check for item
	item, ok := c.cache[key]
	if !ok || !Compare(item.value, cmp) {
		return false
	}

	// Invalidate item
	c.invalid(key, item.value)

	// Update item + expiry
	item.value = swp
	item.expiry = time.Now().Add(c.ttl)

	return ok
}

func (c *TTLCache[K, V]) Swap(key K, swp V) V {
	c.Lock()
	old := c.SwapUnsafe(key, swp)
	c.Unlock()
	return old
}

// SwapUnsafe is the mutex-unprotected logic for Cache.Swap().
func (c *TTLCache[K, V]) SwapUnsafe(key K, swp V) V {
	// Check for item
	item, ok := c.cache[key]
	if !ok {
		var value V
		return value
	}

	// invalidate old item
	c.invalid(key, item.value)
	old := item.value

	// update item + expiry
	item.value = swp
	item.expiry = time.Now().Add(c.ttl)

	return old
}

func (c *TTLCache[K, V]) Has(key K) bool {
	c.Lock()
	ok := c.HasUnsafe(key)
	c.Unlock()
	return ok
}

// HasUnsafe is the mutex-unprotected logic for Cache.Has().
func (c *TTLCache[K, V]) HasUnsafe(key K) bool {
	_, ok := c.cache[key]
	return ok
}

func (c *TTLCache[K, V]) Invalidate(key K) bool {
	c.Lock()
	defer c.Unlock()
	return c.InvalidateUnsafe(key)
}

// InvalidateUnsafe is mutex-unprotected logic for Cache.Invalidate().
func (c *TTLCache[K, V]) InvalidateUnsafe(key K) bool {
	// Check if we have item with key
	item, ok := c.cache[key]
	if !ok {
		return false
	}

	// Call hook, remove from cache
	c.invalid(key, item.value)
	delete(c.cache, key)
	return true
}

func (c *TTLCache[K, V]) Clear() {
	c.Lock()
	defer c.Unlock()
	c.ClearUnsafe()
}

// ClearUnsafe is mutex-unprotected logic for Cache.Clean().
func (c *TTLCache[K, V]) ClearUnsafe() {
	for key, item := range c.cache {
		c.invalid(key, item.value)
		delete(c.cache, key)
	}
}

func (c *TTLCache[K, V]) Size() int {
	c.Lock()
	sz := c.SizeUnsafe()
	c.Unlock()
	return sz
}

// SizeUnsafe is mutex unprotected logic for Cache.Size().
func (c *TTLCache[K, V]) SizeUnsafe() int {
	return len(c.cache)
}

// entry represents an item in the cache, with
// it's currently calculated expiry time.
type entry[Value any] struct {
	value  Value
	expiry time.Time
}
[security] transport.Controller{} and transport.Transport{} security and performance improvements (#564) * cache transports in controller by privkey-generated pubkey, add retry logic to transport requests Signed-off-by: kim <grufwub@gmail.com> * update code comments, defer mutex unlocks Signed-off-by: kim <grufwub@gmail.com> * add count to 'performing request' log message Signed-off-by: kim <grufwub@gmail.com> * reduce repeated conversions of same url.URL object Signed-off-by: kim <grufwub@gmail.com> * move worker.Worker to concurrency subpackage, add WorkQueue type, limit transport http client use by WorkQueue Signed-off-by: kim <grufwub@gmail.com> * fix security advisories regarding max outgoing conns, max rsp body size - implemented by a new httpclient.Client{} that wraps an underlying client with a queue to limit connections, and limit reader wrapping a response body with a configured maximum size - update pub.HttpClient args passed around to be this new httpclient.Client{} Signed-off-by: kim <grufwub@gmail.com> * add httpclient tests, move ip validation to separate package + change mechanism Signed-off-by: kim <grufwub@gmail.com> * fix merge conflicts Signed-off-by: kim <grufwub@gmail.com> * use singular mutex in transport rather than separate signer mus Signed-off-by: kim <grufwub@gmail.com> * improved useragent string Signed-off-by: kim <grufwub@gmail.com> * add note regarding missing test Signed-off-by: kim <grufwub@gmail.com> * remove useragent field from transport (instead store in controller) Signed-off-by: kim <grufwub@gmail.com> * shutup linter Signed-off-by: kim <grufwub@gmail.com> * reset other signing headers on each loop iteration Signed-off-by: kim <grufwub@gmail.com> * respect request ctx during retry-backoff sleep period Signed-off-by: kim <grufwub@gmail.com> * use external pkg with docs explaining performance "hack" Signed-off-by: kim <grufwub@gmail.com> * use http package constants instead of string method literals Signed-off-by: kim <grufwub@gmail.com> * add license file headers Signed-off-by: kim <grufwub@gmail.com> * update code comment to match new func names Signed-off-by: kim <grufwub@gmail.com> * updates to user-agent string Signed-off-by: kim <grufwub@gmail.com> * update signed testrig models to fit with new transport logic (instead uses separate signer now) Signed-off-by: kim <grufwub@gmail.com> * fuck you linter Signed-off-by: kim <grufwub@gmail.com> 2022-05-15 10:16:43 +01:00			`package cache`

			`import (`
			`"context"`
			`"sync"`
			`"time"`

			`"codeberg.org/gruf/go-runners"`
			`)`

			`// TTLCache is the underlying Cache implementation, providing both the base`
			`// Cache interface and access to "unsafe" methods so that you may build your`
			`// customized caches ontop of this structure.`
			`type TTLCache[Key comparable, Value any] struct {`
			`cache map[Key](*entry[Value])`
			`evict Hook[Key, Value] // the evict hook is called when an item is evicted from the cache, includes manual delete`
			`invalid Hook[Key, Value] // the invalidate hook is called when an item's data in the cache is invalidated`
			`ttl time.Duration // ttl is the item TTL`
			`svc runners.Service // svc manages running of the cache eviction routine`
			`mu sync.Mutex // mu protects TTLCache for concurrent access`
			`}`

			`// Init performs Cache initialization, this MUST be called.`
			`func (c *TTLCache[K, V]) Init() {`
			`c.cache = make(map[K](*entry[V]), 100)`
			`c.evict = emptyHook[K, V]`
			`c.invalid = emptyHook[K, V]`
			`c.ttl = time.Minute * 5`
			`}`

			`func (c *TTLCache[K, V]) Start(freq time.Duration) bool {`
			`// Nothing to start`
			`if freq <= 0 {`
			`return false`
			`}`

			`// Track state of starting`
			`done := make(chan struct{})`
			`started := false`

			`go func() {`
			`ran := c.svc.Run(func(ctx context.Context) {`
			`// Successfully started`
			`started = true`
			`close(done)`

			`// start routine`
			`c.run(ctx, freq)`
			`})`

			`// failed to start`
			`if !ran {`
			`close(done)`
			`}`
			`}()`

			`<-done`
			`return started`
			`}`

			`func (c *TTLCache[K, V]) Stop() bool {`
			`return c.svc.Stop()`
			`}`

			`func (c *TTLCache[K, V]) run(ctx context.Context, freq time.Duration) {`
			`t := time.NewTimer(freq)`
			`for {`
			`select {`
			`// we got stopped`
			`case <-ctx.Done():`
			`if !t.Stop() {`
			`<-t.C`
			`}`
			`return`

			`// next tick`
			`case <-t.C:`
			`c.sweep()`
			`t.Reset(freq)`
			`}`
			`}`
			`}`

			`// sweep attempts to evict expired items (with callback!) from cache.`
			`func (c *TTLCache[K, V]) sweep() {`
			`// Lock and defer unlock (in case of hook panic)`
			`c.mu.Lock()`
			`defer c.mu.Unlock()`

			`// Fetch current time for TTL check`
			`now := time.Now()`

			`// Sweep the cache for old items!`
			`for key, item := range c.cache {`
			`if now.After(item.expiry) {`
			`c.evict(key, item.value)`
			`delete(c.cache, key)`
			`}`
			`}`
			`}`

			`// Lock locks the cache mutex.`
			`func (c *TTLCache[K, V]) Lock() {`
			`c.mu.Lock()`
			`}`

			`// Unlock unlocks the cache mutex.`
			`func (c *TTLCache[K, V]) Unlock() {`
			`c.mu.Unlock()`
			`}`

			`func (c *TTLCache[K, V]) SetEvictionCallback(hook Hook[K, V]) {`
			`// Ensure non-nil hook`
			`if hook == nil {`
			`hook = emptyHook[K, V]`
			`}`

			`// Safely set evict hook`
			`c.Lock()`
			`c.evict = hook`
			`c.Unlock()`
			`}`

			`func (c *TTLCache[K, V]) SetInvalidateCallback(hook Hook[K, V]) {`
			`// Ensure non-nil hook`
			`if hook == nil {`
			`hook = emptyHook[K, V]`
			`}`

			`// Safely set invalidate hook`
			`c.Lock()`
			`c.invalid = hook`
			`c.Unlock()`
			`}`

			`func (c *TTLCache[K, V]) SetTTL(ttl time.Duration, update bool) {`
			`// Safely update TTL`
			`c.Lock()`
			`diff := ttl - c.ttl`
			`c.ttl = ttl`

			`if update {`
			`// Update existing cache entries`
			`for _, entry := range c.cache {`
			`entry.expiry.Add(diff)`
			`}`
			`}`

			`// We're done`
			`c.Unlock()`
			`}`

			`func (c *TTLCache[K, V]) Get(key K) (V, bool) {`
			`c.Lock()`
			`value, ok := c.GetUnsafe(key)`
			`c.Unlock()`
			`return value, ok`
			`}`

			`// GetUnsafe is the mutex-unprotected logic for Cache.Get().`
			`func (c *TTLCache[K, V]) GetUnsafe(key K) (V, bool) {`
			`item, ok := c.cache[key]`
			`if !ok {`
			`var value V`
			`return value, false`
			`}`
			`item.expiry = time.Now().Add(c.ttl)`
			`return item.value, true`
			`}`

			`func (c *TTLCache[K, V]) Put(key K, value V) bool {`
			`c.Lock()`
			`success := c.PutUnsafe(key, value)`
			`c.Unlock()`
			`return success`
			`}`

			`// PutUnsafe is the mutex-unprotected logic for Cache.Put().`
			`func (c *TTLCache[K, V]) PutUnsafe(key K, value V) bool {`
			`// If already cached, return`
			`if _, ok := c.cache[key]; ok {`
			`return false`
			`}`

			`// Create new cached item`
			`c.cache[key] = &entry[V]{`
			`value: value,`
			`expiry: time.Now().Add(c.ttl),`
			`}`

			`return true`
			`}`

			`func (c *TTLCache[K, V]) Set(key K, value V) {`
			`c.Lock()`
			`defer c.Unlock() // defer in case of hook panic`
			`c.SetUnsafe(key, value)`
			`}`

			`// SetUnsafe is the mutex-unprotected logic for Cache.Set(), it calls externally-set functions.`
			`func (c *TTLCache[K, V]) SetUnsafe(key K, value V) {`
			`item, ok := c.cache[key]`
			`if ok {`
			`// call invalidate hook`
			`c.invalid(key, item.value)`
			`} else {`
			`// alloc new item`
			`item = &entry[V]{}`
			`c.cache[key] = item`
			`}`

			`// Update the item + expiry`
			`item.value = value`
			`item.expiry = time.Now().Add(c.ttl)`
			`}`

			`func (c *TTLCache[K, V]) CAS(key K, cmp V, swp V) bool {`
			`c.Lock()`
			`ok := c.CASUnsafe(key, cmp, swp)`
			`c.Unlock()`
			`return ok`
			`}`

			`// CASUnsafe is the mutex-unprotected logic for Cache.CAS().`
			`func (c *TTLCache[K, V]) CASUnsafe(key K, cmp V, swp V) bool {`
			`// Check for item`
			`item, ok := c.cache[key]`
			`if !ok \|\| !Compare(item.value, cmp) {`
			`return false`
			`}`

			`// Invalidate item`
			`c.invalid(key, item.value)`

			`// Update item + expiry`
			`item.value = swp`
			`item.expiry = time.Now().Add(c.ttl)`

			`return ok`
			`}`

			`func (c *TTLCache[K, V]) Swap(key K, swp V) V {`
			`c.Lock()`
			`old := c.SwapUnsafe(key, swp)`
			`c.Unlock()`
			`return old`
			`}`

			`// SwapUnsafe is the mutex-unprotected logic for Cache.Swap().`
			`func (c *TTLCache[K, V]) SwapUnsafe(key K, swp V) V {`
			`// Check for item`
			`item, ok := c.cache[key]`
			`if !ok {`
			`var value V`
			`return value`
			`}`

			`// invalidate old item`
			`c.invalid(key, item.value)`
			`old := item.value`

			`// update item + expiry`
			`item.value = swp`
			`item.expiry = time.Now().Add(c.ttl)`

			`return old`
			`}`

			`func (c *TTLCache[K, V]) Has(key K) bool {`
			`c.Lock()`
			`ok := c.HasUnsafe(key)`
			`c.Unlock()`
			`return ok`
			`}`

			`// HasUnsafe is the mutex-unprotected logic for Cache.Has().`
			`func (c *TTLCache[K, V]) HasUnsafe(key K) bool {`
			`_, ok := c.cache[key]`
			`return ok`
			`}`

			`func (c *TTLCache[K, V]) Invalidate(key K) bool {`
			`c.Lock()`
			`defer c.Unlock()`
			`return c.InvalidateUnsafe(key)`
			`}`

			`// InvalidateUnsafe is mutex-unprotected logic for Cache.Invalidate().`
			`func (c *TTLCache[K, V]) InvalidateUnsafe(key K) bool {`
			`// Check if we have item with key`
			`item, ok := c.cache[key]`
			`if !ok {`
			`return false`
			`}`

			`// Call hook, remove from cache`
			`c.invalid(key, item.value)`
			`delete(c.cache, key)`
			`return true`
			`}`

			`func (c *TTLCache[K, V]) Clear() {`
			`c.Lock()`
			`defer c.Unlock()`
			`c.ClearUnsafe()`
			`}`

			`// ClearUnsafe is mutex-unprotected logic for Cache.Clean().`
			`func (c *TTLCache[K, V]) ClearUnsafe() {`
			`for key, item := range c.cache {`
			`c.invalid(key, item.value)`
			`delete(c.cache, key)`
			`}`
			`}`

			`func (c *TTLCache[K, V]) Size() int {`
			`c.Lock()`
			`sz := c.SizeUnsafe()`
			`c.Unlock()`
			`return sz`
			`}`

			`// SizeUnsafe is mutex unprotected logic for Cache.Size().`
			`func (c *TTLCache[K, V]) SizeUnsafe() int {`
			`return len(c.cache)`
			`}`

			`// entry represents an item in the cache, with`
			`// it's currently calculated expiry time.`
			`type entry[Value any] struct {`
			`value Value`
			`expiry time.Time`
			`}`