// Copyright (c) 2015-2021 MinIO, Inc. // // This file is part of MinIO Object Storage stack // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU Affero General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // This program is distributed in the hope that it will be useful // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Affero General Public License for more details. // // You should have received a copy of the GNU Affero General Public License // along with this program. If not, see . package cmd import ( "bytes" "context" "errors" "fmt" "net/http" "path" "runtime/debug" "sort" "strings" "sync" "time" "github.com/klauspost/compress/s2" "github.com/minio/minio/internal/hash" "github.com/minio/minio/internal/logger" "github.com/minio/pkg/console" "github.com/tinylib/msgp/msgp" ) //go:generate msgp -file $GOFILE -unexported // a bucketMetacache keeps track of all caches generated // for a bucket. type bucketMetacache struct { // Name of bucket bucket string // caches indexed by id. caches map[string]metacache // cache ids indexed by root paths cachesRoot map[string][]string `msg:"-"` // Internal state mu sync.RWMutex `msg:"-"` updated bool `msg:"-"` transient bool `msg:"-"` // bucket used for non-persisted caches. } // newBucketMetacache creates a new bucketMetacache. // Optionally remove all existing caches. func newBucketMetacache(bucket string, cleanup bool) *bucketMetacache { if cleanup { // Recursively delete all caches. objAPI := newObjectLayerFn() ez, ok := objAPI.(*erasureServerPools) if ok { ctx := context.Background() ez.renameAll(ctx, minioMetaBucket, metacachePrefixForID(bucket, slashSeparator)) } } return &bucketMetacache{ bucket: bucket, caches: make(map[string]metacache, 10), cachesRoot: make(map[string][]string, 10), } } func (b *bucketMetacache) debugf(format string, data ...interface{}) { if serverDebugLog { console.Debugf(format+"\n", data...) } } // loadBucketMetaCache will load the cache from the object layer. // If the cache cannot be found a new one is created. func loadBucketMetaCache(ctx context.Context, bucket string) (*bucketMetacache, error) { objAPI := newObjectLayerFn() for objAPI == nil { select { case <-ctx.Done(): return nil, ctx.Err() default: time.Sleep(250 * time.Millisecond) } objAPI = newObjectLayerFn() if objAPI == nil { logger.LogIf(ctx, fmt.Errorf("loadBucketMetaCache: object layer not ready. bucket: %q", bucket)) } } var meta bucketMetacache var decErr error // Use global context for this. r, err := objAPI.GetObjectNInfo(GlobalContext, minioMetaBucket, pathJoin("buckets", bucket, ".metacache", "index.s2"), nil, http.Header{}, readLock, ObjectOptions{}) if err == nil { dec := s2DecPool.Get().(*s2.Reader) dec.Reset(r) decErr = meta.DecodeMsg(msgp.NewReader(dec)) dec.Reset(nil) r.Close() s2DecPool.Put(dec) } if err != nil { switch err.(type) { case ObjectNotFound: err = nil case InsufficientReadQuorum: // Cache is likely lost. Clean up and return new. return newBucketMetacache(bucket, true), nil default: logger.LogIf(ctx, err) } return newBucketMetacache(bucket, false), err } if decErr != nil { if errors.Is(err, context.Canceled) { return newBucketMetacache(bucket, false), err } // Log the error, but assume the data is lost and return a fresh bucket. // Otherwise a broken cache will never recover. logger.LogIf(ctx, decErr) return newBucketMetacache(bucket, true), nil } // Sanity check... if meta.bucket != bucket { logger.Info("loadBucketMetaCache: loaded cache name mismatch, want %s, got %s. Discarding.", bucket, meta.bucket) return newBucketMetacache(bucket, true), nil } meta.cachesRoot = make(map[string][]string, len(meta.caches)/10) // Index roots for id, cache := range meta.caches { meta.cachesRoot[cache.root] = append(meta.cachesRoot[cache.root], id) } return &meta, nil } // save the bucket cache to the object storage. func (b *bucketMetacache) save(ctx context.Context) error { if b.transient { return nil } objAPI := newObjectLayerFn() if objAPI == nil { return errServerNotInitialized } // Keep lock while we marshal. // We need a write lock since we update 'updated' b.mu.Lock() if !b.updated { b.mu.Unlock() return nil } // Save as s2 compressed msgpack tmp := bytes.NewBuffer(make([]byte, 0, b.Msgsize())) enc := s2.NewWriter(tmp) err := msgp.Encode(enc, b) if err != nil { b.mu.Unlock() return err } err = enc.Close() if err != nil { b.mu.Unlock() return err } b.updated = false b.mu.Unlock() hr, err := hash.NewReader(tmp, int64(tmp.Len()), "", "", int64(tmp.Len())) if err != nil { return err } _, err = objAPI.PutObject(ctx, minioMetaBucket, pathJoin("buckets", b.bucket, ".metacache", "index.s2"), NewPutObjReader(hr), ObjectOptions{}) logger.LogIf(ctx, err) return err } // findCache will attempt to find a matching cache for the provided options. // If a cache with the same ID exists already it will be returned. // If none can be found a new is created with the provided ID. func (b *bucketMetacache) findCache(o listPathOptions) metacache { if b == nil { logger.Info("bucketMetacache.findCache: nil cache for bucket %s", o.Bucket) return metacache{} } if o.Bucket != b.bucket && !b.transient { logger.Info("bucketMetacache.findCache: bucket %s does not match this bucket %s", o.Bucket, b.bucket) debug.PrintStack() return metacache{} } extend := globalAPIConfig.getExtendListLife() // Grab a write lock, since we create one if we cannot find one. if o.Create { b.mu.Lock() defer b.mu.Unlock() } else { b.mu.RLock() defer b.mu.RUnlock() } // Check if exists already. if c, ok := b.caches[o.ID]; ok { b.debugf("returning existing %v", o.ID) return c } // No need to do expensive checks on transients. if b.transient { if !o.Create { return metacache{ id: o.ID, bucket: o.Bucket, status: scanStateNone, } } // Create new best := o.newMetacache() b.caches[o.ID] = best b.updated = true b.debugf("returning new cache %s, bucket: %v", best.id, best.bucket) return best } var best metacache rootSplit := strings.Split(o.BaseDir, slashSeparator) for i := range rootSplit { interesting := b.cachesRoot[path.Join(rootSplit[:i+1]...)] for _, id := range interesting { cached, ok := b.caches[id] if !ok { continue } if !cached.matches(&o, extend) { continue } if cached.started.Before(best.started) { b.debugf("cache %s disregarded - we have a better", cached.id) // If we already have a newer, keep that. continue } best = cached } } if !best.started.IsZero() { if o.Create { best.lastHandout = UTCNow() b.caches[best.id] = best b.updated = true } b.debugf("returning cached %s, status: %v, ended: %v", best.id, best.status, best.ended) return best } if !o.Create { return metacache{ id: o.ID, bucket: o.Bucket, status: scanStateNone, } } // Create new and add. best = o.newMetacache() b.caches[o.ID] = best b.cachesRoot[best.root] = append(b.cachesRoot[best.root], best.id) b.updated = true b.debugf("returning new cache %s, bucket: %v", best.id, best.bucket) return best } // cleanup removes redundant and outdated entries. func (b *bucketMetacache) cleanup() { // Entries to remove. remove := make(map[string]struct{}) currentCycle := intDataUpdateTracker.current() // Test on a copy // cleanup is the only one deleting caches. caches, rootIdx := b.cloneCaches() for id, cache := range caches { if b.transient && time.Since(cache.lastUpdate) > 10*time.Minute && time.Since(cache.lastHandout) > 10*time.Minute { // Keep transient caches only for 15 minutes. remove[id] = struct{}{} continue } if !cache.worthKeeping(currentCycle) { b.debugf("cache %s not worth keeping", id) remove[id] = struct{}{} continue } if cache.id != id { logger.Info("cache ID mismatch %s != %s", id, cache.id) remove[id] = struct{}{} continue } if cache.bucket != b.bucket && !b.transient { logger.Info("cache bucket mismatch %s != %s", b.bucket, cache.bucket) remove[id] = struct{}{} continue } } // Check all non-deleted against eachother. // O(n*n), but should still be rather quick. for id, cache := range caches { if b.transient { break } if _, ok := remove[id]; ok { continue } interesting := interestingCaches(cache.root, rootIdx) for _, id2 := range interesting { if _, ok := remove[id2]; ok || id2 == id { // Don't check against one we are already removing continue } cache2, ok := caches[id2] if !ok { continue } if cache.canBeReplacedBy(&cache2) { b.debugf("cache %s can be replaced by %s", id, cache2.id) remove[id] = struct{}{} break } else { b.debugf("cache %s can be NOT replaced by %s", id, cache2.id) } } } // If above limit, remove the caches with the oldest handout time. if len(caches)-len(remove) > metacacheMaxEntries { remainCaches := make([]metacache, 0, len(caches)-len(remove)) for id, cache := range caches { if _, ok := remove[id]; ok { continue } remainCaches = append(remainCaches, cache) } if len(remainCaches) > metacacheMaxEntries { // Sort oldest last... sort.Slice(remainCaches, func(i, j int) bool { return remainCaches[i].lastHandout.Before(remainCaches[j].lastHandout) }) // Keep first metacacheMaxEntries... for _, cache := range remainCaches[metacacheMaxEntries:] { if time.Since(cache.lastHandout) > 30*time.Minute { remove[cache.id] = struct{}{} } } } } for id := range remove { b.deleteCache(id) } } // Potentially interesting caches. // Will only add root if request is for root. func interestingCaches(root string, cachesRoot map[string][]string) []string { var interesting []string rootSplit := strings.Split(root, slashSeparator) for i := range rootSplit { want := path.Join(rootSplit[:i+1]...) interesting = append(interesting, cachesRoot[want]...) } return interesting } // updateCacheEntry will update a cache. // Returns the updated status. func (b *bucketMetacache) updateCacheEntry(update metacache) (metacache, error) { b.mu.Lock() defer b.mu.Unlock() existing, ok := b.caches[update.id] if !ok { return update, errFileNotFound } existing.update(update) b.caches[update.id] = existing b.updated = true return existing, nil } // cloneCaches will return a clone of all current caches. func (b *bucketMetacache) cloneCaches() (map[string]metacache, map[string][]string) { b.mu.RLock() defer b.mu.RUnlock() dst := make(map[string]metacache, len(b.caches)) for k, v := range b.caches { dst[k] = v } // Copy indexes dst2 := make(map[string][]string, len(b.cachesRoot)) for k, v := range b.cachesRoot { tmp := make([]string, len(v)) copy(tmp, v) dst2[k] = tmp } return dst, dst2 } // deleteAll will delete all on disk data for ALL caches. // Deletes are performed concurrently. func (b *bucketMetacache) deleteAll() { ctx := context.Background() ez, ok := newObjectLayerFn().(*erasureServerPools) if !ok { logger.LogIf(ctx, errors.New("bucketMetacache: expected objAPI to be *erasurePools")) return } b.mu.Lock() defer b.mu.Unlock() b.updated = true if !b.transient { // Delete all. ez.renameAll(ctx, minioMetaBucket, metacachePrefixForID(b.bucket, slashSeparator)) b.caches = make(map[string]metacache, 10) b.cachesRoot = make(map[string][]string, 10) return } // Transient are in different buckets. var wg sync.WaitGroup for id := range b.caches { wg.Add(1) go func(cache metacache) { defer wg.Done() ez.renameAll(ctx, minioMetaBucket, metacachePrefixForID(cache.bucket, cache.id)) }(b.caches[id]) } wg.Wait() b.caches = make(map[string]metacache, 10) } // deleteCache will delete a specific cache and all files related to it across the cluster. func (b *bucketMetacache) deleteCache(id string) { b.mu.Lock() c, ok := b.caches[id] if ok { // Delete from root map. list := b.cachesRoot[c.root] for i, lid := range list { if id == lid { list = append(list[:i], list[i+1:]...) break } } b.cachesRoot[c.root] = list delete(b.caches, id) b.updated = true } b.mu.Unlock() if ok { c.delete(context.Background()) } }