// Copyright 2024 The Hugo Authors. All rights reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package dynacache import ( "context" "fmt" "math" "path" "regexp" "runtime" "sync" "time" "github.com/bep/lazycache" "github.com/bep/logg" "github.com/gohugoio/hugo/common/herrors" "github.com/gohugoio/hugo/common/loggers" "github.com/gohugoio/hugo/common/paths" "github.com/gohugoio/hugo/common/rungroup" "github.com/gohugoio/hugo/config" "github.com/gohugoio/hugo/helpers" "github.com/gohugoio/hugo/identity" "github.com/gohugoio/hugo/resources/resource" ) const minMaxSize = 10 // New creates a new cache. func New(opts Options) *Cache { if opts.CheckInterval == 0 { opts.CheckInterval = time.Second * 2 } if opts.MaxSize == 0 { opts.MaxSize = 100000 } if opts.Log == nil { panic("nil Log") } if opts.MinMaxSize == 0 { opts.MinMaxSize = 30 } stats := &stats{ opts: opts, adjustmentFactor: 1.0, currentMaxSize: opts.MaxSize, availableMemory: config.GetMemoryLimit(), } infol := opts.Log.InfoCommand("dynacache") c := &Cache{ partitions: make(map[string]PartitionManager), opts: opts, stats: stats, infol: infol, } c.stop = c.start() return c } // Options for the cache. type Options struct { Log loggers.Logger CheckInterval time.Duration MaxSize int MinMaxSize int Running bool } // Options for a partition. type OptionsPartition struct { // When to clear the this partition. ClearWhen ClearWhen // Weight is a number between 1 and 100 that indicates how, in general, how big this partition may get. Weight int } func (o OptionsPartition) WeightFraction() float64 { return float64(o.Weight) / 100 } func (o OptionsPartition) CalculateMaxSize(maxSizePerPartition int) int { return int(math.Floor(float64(maxSizePerPartition) * o.WeightFraction())) } // A dynamic partitioned cache. type Cache struct { mu sync.RWMutex partitions map[string]PartitionManager opts Options infol logg.LevelLogger stats *stats stopOnce sync.Once stop func() } // ClearMatching clears all partition for which the predicate returns true. func (c *Cache) ClearMatching(predicate func(k, v any) bool) { g := rungroup.Run[PartitionManager](context.Background(), rungroup.Config[PartitionManager]{ NumWorkers: len(c.partitions), Handle: func(ctx context.Context, partition PartitionManager) error { partition.clearMatching(predicate) return nil }, }) for _, p := range c.partitions { g.Enqueue(p) } g.Wait() } // ClearOnRebuild prepares the cache for a new rebuild taking the given changeset into account. func (c *Cache) ClearOnRebuild(changeset ...identity.Identity) { g := rungroup.Run[PartitionManager](context.Background(), rungroup.Config[PartitionManager]{ NumWorkers: len(c.partitions), Handle: func(ctx context.Context, partition PartitionManager) error { partition.clearOnRebuild(changeset...) return nil }, }) for _, p := range c.partitions { g.Enqueue(p) } g.Wait() // Clear any entries marked as stale above. g = rungroup.Run[PartitionManager](context.Background(), rungroup.Config[PartitionManager]{ NumWorkers: len(c.partitions), Handle: func(ctx context.Context, partition PartitionManager) error { partition.clearStale() return nil }, }) for _, p := range c.partitions { g.Enqueue(p) } g.Wait() } type keysProvider interface { Keys() []string } // Keys returns a list of keys in all partitions. func (c *Cache) Keys(predicate func(s string) bool) []string { if predicate == nil { predicate = func(s string) bool { return true } } var keys []string for pn, g := range c.partitions { pkeys := g.(keysProvider).Keys() for _, k := range pkeys { p := path.Join(pn, k) if predicate(p) { keys = append(keys, p) } } } return keys } func calculateMaxSizePerPartition(maxItemsTotal, totalWeightQuantity, numPartitions int) int { if numPartitions == 0 { panic("numPartitions must be > 0") } if totalWeightQuantity == 0 { panic("totalWeightQuantity must be > 0") } avgWeight := float64(totalWeightQuantity) / float64(numPartitions) return int(math.Floor(float64(maxItemsTotal) / float64(numPartitions) * (100.0 / avgWeight))) } // Stop stops the cache. func (c *Cache) Stop() { c.stopOnce.Do(func() { c.stop() }) } func (c *Cache) adjustCurrentMaxSize() { c.mu.RLock() defer c.mu.RUnlock() if len(c.partitions) == 0 { return } var m runtime.MemStats runtime.ReadMemStats(&m) s := c.stats s.memstatsCurrent = m // fmt.Printf("\n\nAvailable = %v\nAlloc = %v\nTotalAlloc = %v\nSys = %v\nNumGC = %v\nMaxSize = %d\nAdjustmentFactor=%f\n\n", helpers.FormatByteCount(s.availableMemory), helpers.FormatByteCount(m.Alloc), helpers.FormatByteCount(m.TotalAlloc), helpers.FormatByteCount(m.Sys), m.NumGC, c.stats.currentMaxSize, s.adjustmentFactor) if s.availableMemory >= s.memstatsCurrent.Alloc { if s.adjustmentFactor <= 1.0 { s.adjustmentFactor += 0.2 } } else { // We're low on memory. s.adjustmentFactor -= 0.4 } if s.adjustmentFactor <= 0 { s.adjustmentFactor = 0.05 } if !s.adjustCurrentMaxSize() { return } totalWeight := 0 for _, pm := range c.partitions { totalWeight += pm.getOptions().Weight } maxSizePerPartition := calculateMaxSizePerPartition(c.stats.currentMaxSize, totalWeight, len(c.partitions)) evicted := 0 for _, p := range c.partitions { evicted += p.adjustMaxSize(p.getOptions().CalculateMaxSize(maxSizePerPartition)) } if evicted > 0 { c.infol. WithFields( logg.Fields{ {Name: "evicted", Value: evicted}, {Name: "numGC", Value: m.NumGC}, {Name: "limit", Value: helpers.FormatByteCount(c.stats.availableMemory)}, {Name: "alloc", Value: helpers.FormatByteCount(m.Alloc)}, {Name: "totalAlloc", Value: helpers.FormatByteCount(m.TotalAlloc)}, }, ).Logf("adjusted partitions' max size") } } func (c *Cache) start() func() { ticker := time.NewTicker(c.opts.CheckInterval) quit := make(chan struct{}) go func() { for { select { case <-ticker.C: c.adjustCurrentMaxSize() case <-quit: ticker.Stop() return } } }() return func() { close(quit) } } var partitionNameRe = regexp.MustCompile(`^\/[a-zA-Z0-9]{4}(\/[a-zA-Z0-9]+)?(\/[a-zA-Z0-9]+)?`) // GetOrCreatePartition gets or creates a partition with the given name. func GetOrCreatePartition[K comparable, V any](c *Cache, name string, opts OptionsPartition) *Partition[K, V] { if c == nil { panic("nil Cache") } if opts.Weight < 1 || opts.Weight > 100 { panic("invalid Weight, must be between 1 and 100") } if partitionNameRe.FindString(name) != name { panic(fmt.Sprintf("invalid partition name %q", name)) } c.mu.RLock() p, found := c.partitions[name] c.mu.RUnlock() if found { return p.(*Partition[K, V]) } c.mu.Lock() defer c.mu.Unlock() // Double check. p, found = c.partitions[name] if found { return p.(*Partition[K, V]) } // At this point, we don't know the the number of partitions or their configuration, but // this will be re-adjusted later. const numberOfPartitionsEstimate = 10 maxSize := opts.CalculateMaxSize(c.opts.MaxSize / numberOfPartitionsEstimate) // Create a new partition and cache it. partition := &Partition[K, V]{ c: lazycache.New(lazycache.Options[K, V]{MaxEntries: maxSize}), maxSize: maxSize, trace: c.opts.Log.Logger().WithLevel(logg.LevelTrace).WithField("partition", name), opts: opts, } c.partitions[name] = partition return partition } // Partition is a partition in the cache. type Partition[K comparable, V any] struct { c *lazycache.Cache[K, V] zero V trace logg.LevelLogger opts OptionsPartition maxSize int } // GetOrCreate gets or creates a value for the given key. func (p *Partition[K, V]) GetOrCreate(key K, create func(key K) (V, error)) (V, error) { v, _, err := p.c.GetOrCreate(key, create) return v, err } // GetOrCreateWitTimeout gets or creates a value for the given key and times out if the create function // takes too long. func (p *Partition[K, V]) GetOrCreateWitTimeout(key K, duration time.Duration, create func(key K) (V, error)) (V, error) { resultch := make(chan V, 1) errch := make(chan error, 1) go func() { v, _, err := p.c.GetOrCreate(key, create) if err != nil { errch <- err return } resultch <- v }() select { case v := <-resultch: return v, nil case err := <-errch: return p.zero, err case <-time.After(duration): return p.zero, &herrors.TimeoutError{ Duration: duration, } } } func (p *Partition[K, V]) clearMatching(predicate func(k, v any) bool) { p.c.DeleteFunc(func(key K, v V) bool { if predicate(key, v) { p.trace.Log( logg.StringFunc( func() string { return fmt.Sprintf("clearing cache key %v", key) }, ), ) return true } return false }) } func (p *Partition[K, V]) clearOnRebuild(changeset ...identity.Identity) { opts := p.getOptions() if opts.ClearWhen == ClearNever { return } if opts.ClearWhen == ClearOnRebuild { // Clear all. p.Clear() return } depsFinder := identity.NewFinder(identity.FinderConfig{}) shouldDelete := func(key K, v V) bool { // We always clear elements marked as stale. if resource.IsStaleAny(v) { return true } // Now check if this entry has changed based on the changeset // based on filesystem events. if len(changeset) == 0 { // Nothing changed. return false } var probablyDependent bool identity.WalkIdentitiesShallow(v, func(level int, id2 identity.Identity) bool { for _, id := range changeset { if r := depsFinder.Contains(id, id2, -1); r > 0 { // It's probably dependent, evict from cache. probablyDependent = true return true } } return false }) return probablyDependent } // First pass. // Second pass needs to be done in a separate loop to catch any // elements marked as stale in the other partitions. p.c.DeleteFunc(func(key K, v V) bool { if shouldDelete(key, v) { p.trace.Log( logg.StringFunc( func() string { return fmt.Sprintf("first pass: clearing cache key %v", key) }, ), ) resource.MarkStale(v) return true } return false }) } func (p *Partition[K, V]) Keys() []K { var keys []K p.c.DeleteFunc(func(key K, v V) bool { keys = append(keys, key) return false }) return keys } func (p *Partition[K, V]) clearStale() { p.c.DeleteFunc(func(key K, v V) bool { isStale := resource.IsStaleAny(v) if isStale { p.trace.Log( logg.StringFunc( func() string { return fmt.Sprintf("second pass: clearing cache key %v", key) }, ), ) } return isStale }) } // adjustMaxSize adjusts the max size of the and returns the number of items evicted. func (p *Partition[K, V]) adjustMaxSize(newMaxSize int) int { if newMaxSize < minMaxSize { newMaxSize = minMaxSize } p.maxSize = newMaxSize // fmt.Println("Adjusting max size of partition from", oldMaxSize, "to", newMaxSize) return p.c.Resize(newMaxSize) } func (p *Partition[K, V]) getMaxSize() int { return p.maxSize } func (p *Partition[K, V]) getOptions() OptionsPartition { return p.opts } func (p *Partition[K, V]) Clear() { p.c.DeleteFunc(func(key K, v V) bool { return true }) } func (p *Partition[K, V]) Get(ctx context.Context, key K) (V, bool) { return p.c.Get(key) } type PartitionManager interface { adjustMaxSize(addend int) int getMaxSize() int getOptions() OptionsPartition clearOnRebuild(changeset ...identity.Identity) clearMatching(predicate func(k, v any) bool) clearStale() } const ( ClearOnRebuild ClearWhen = iota + 1 ClearOnChange ClearNever ) type ClearWhen int type stats struct { opts Options memstatsCurrent runtime.MemStats currentMaxSize int availableMemory uint64 adjustmentFactor float64 } func (s *stats) adjustCurrentMaxSize() bool { newCurrentMaxSize := int(math.Floor(float64(s.opts.MaxSize) * s.adjustmentFactor)) if newCurrentMaxSize < s.opts.MaxSize { newCurrentMaxSize = int(s.opts.MinMaxSize) } changed := newCurrentMaxSize != s.currentMaxSize s.currentMaxSize = newCurrentMaxSize return changed } // CleanKey turns s into a format suitable for a cache key for this package. // The key will be a Unix-styled path with a leading slash but no trailing slash. func CleanKey(s string) string { return path.Clean(paths.ToSlashPreserveLeading(s)) }