// Copyright 2020 The go-ethereum Authors // This file is part of the go-ethereum library. // // The go-ethereum library is free software: you can redistribute it and/or modify // it under the terms of the GNU Lesser General Public License as published by // the Free Software Foundation, either version 3 of the License, or // (at your option) any later version. // // The go-ethereum library 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 Lesser General Public License for more details. // // You should have received a copy of the GNU Lesser General Public License // along with the go-ethereum library. If not, see . package state import ( "sync" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/metrics" "github.com/harmony-one/harmony/internal/utils" ) var ( // triePrefetchMetricsPrefix is the prefix under which to publish the metrics. triePrefetchMetricsPrefix = "trie/prefetch/" ) // triePrefetcher is an active prefetcher, which receives accounts or storage // items and does trie-loading of them. The goal is to get as much useful content // into the caches as possible. // // Note, the prefetcher's API is not thread safe. type triePrefetcher struct { db Database // Database to fetch trie nodes through root common.Hash // Root hash of the account trie for metrics fetches map[string]Trie // Partially or fully fetcher tries fetchers map[string]*subfetcher // Subfetchers for each trie deliveryMissMeter metrics.Meter accountLoadMeter metrics.Meter accountDupMeter metrics.Meter accountSkipMeter metrics.Meter accountWasteMeter metrics.Meter storageLoadMeter metrics.Meter storageDupMeter metrics.Meter storageSkipMeter metrics.Meter storageWasteMeter metrics.Meter } func newTriePrefetcher(db Database, root common.Hash, namespace string) *triePrefetcher { prefix := triePrefetchMetricsPrefix + namespace p := &triePrefetcher{ db: db, root: root, fetchers: make(map[string]*subfetcher), // Active prefetchers use the fetchers map deliveryMissMeter: metrics.GetOrRegisterMeter(prefix+"/deliverymiss", nil), accountLoadMeter: metrics.GetOrRegisterMeter(prefix+"/account/load", nil), accountDupMeter: metrics.GetOrRegisterMeter(prefix+"/account/dup", nil), accountSkipMeter: metrics.GetOrRegisterMeter(prefix+"/account/skip", nil), accountWasteMeter: metrics.GetOrRegisterMeter(prefix+"/account/waste", nil), storageLoadMeter: metrics.GetOrRegisterMeter(prefix+"/storage/load", nil), storageDupMeter: metrics.GetOrRegisterMeter(prefix+"/storage/dup", nil), storageSkipMeter: metrics.GetOrRegisterMeter(prefix+"/storage/skip", nil), storageWasteMeter: metrics.GetOrRegisterMeter(prefix+"/storage/waste", nil), } return p } // close iterates over all the subfetchers, aborts any that were left spinning // and reports the stats to the metrics subsystem. func (p *triePrefetcher) close() { for _, fetcher := range p.fetchers { fetcher.abort() // safe to do multiple times if metrics.Enabled { if fetcher.root == p.root { p.accountLoadMeter.Mark(int64(len(fetcher.seen))) p.accountDupMeter.Mark(int64(fetcher.dups)) p.accountSkipMeter.Mark(int64(len(fetcher.tasks))) for _, key := range fetcher.used { delete(fetcher.seen, string(key)) } p.accountWasteMeter.Mark(int64(len(fetcher.seen))) } else { p.storageLoadMeter.Mark(int64(len(fetcher.seen))) p.storageDupMeter.Mark(int64(fetcher.dups)) p.storageSkipMeter.Mark(int64(len(fetcher.tasks))) for _, key := range fetcher.used { delete(fetcher.seen, string(key)) } p.storageWasteMeter.Mark(int64(len(fetcher.seen))) } } } // Clear out all fetchers (will crash on a second call, deliberate) p.fetchers = nil } // copy creates a deep-but-inactive copy of the trie prefetcher. Any trie data // already loaded will be copied over, but no goroutines will be started. This // is mostly used in the miner which creates a copy of it's actively mutated // state to be sealed while it may further mutate the state. func (p *triePrefetcher) copy() *triePrefetcher { copy := &triePrefetcher{ db: p.db, root: p.root, fetches: make(map[string]Trie), // Active prefetchers use the fetches map deliveryMissMeter: p.deliveryMissMeter, accountLoadMeter: p.accountLoadMeter, accountDupMeter: p.accountDupMeter, accountSkipMeter: p.accountSkipMeter, accountWasteMeter: p.accountWasteMeter, storageLoadMeter: p.storageLoadMeter, storageDupMeter: p.storageDupMeter, storageSkipMeter: p.storageSkipMeter, storageWasteMeter: p.storageWasteMeter, } // If the prefetcher is already a copy, duplicate the data if p.fetches != nil { for root, fetch := range p.fetches { if fetch == nil { continue } copy.fetches[root] = p.db.CopyTrie(fetch) } return copy } // Otherwise we're copying an active fetcher, retrieve the current states for id, fetcher := range p.fetchers { copy.fetches[id] = fetcher.peek() } return copy } // prefetch schedules a batch of trie items to prefetch. func (p *triePrefetcher) prefetch(owner common.Hash, root common.Hash, keys [][]byte) { // If the prefetcher is an inactive one, bail out if p.fetches != nil { return } // Active fetcher, schedule the retrievals id := p.trieID(owner, root) fetcher := p.fetchers[id] if fetcher == nil { fetcher = newSubfetcher(p.db, p.root, owner, root) p.fetchers[id] = fetcher } fetcher.schedule(keys) } // trie returns the trie matching the root hash, or nil if the prefetcher doesn't // have it. func (p *triePrefetcher) trie(owner common.Hash, root common.Hash) Trie { // If the prefetcher is inactive, return from existing deep copies id := p.trieID(owner, root) if p.fetches != nil { trie := p.fetches[id] if trie == nil { p.deliveryMissMeter.Mark(1) return nil } return p.db.CopyTrie(trie) } // Otherwise the prefetcher is active, bail if no trie was prefetched for this root fetcher := p.fetchers[id] if fetcher == nil { p.deliveryMissMeter.Mark(1) return nil } // Interrupt the prefetcher if it's by any chance still running and return // a copy of any pre-loaded trie. fetcher.abort() // safe to do multiple times trie := fetcher.peek() if trie == nil { p.deliveryMissMeter.Mark(1) return nil } return trie } // used marks a batch of state items used to allow creating statistics as to // how useful or wasteful the prefetcher is. func (p *triePrefetcher) used(owner common.Hash, root common.Hash, used [][]byte) { if fetcher := p.fetchers[p.trieID(owner, root)]; fetcher != nil { fetcher.used = used } } // trieID returns an unique trie identifier consists the trie owner and root hash. func (p *triePrefetcher) trieID(owner common.Hash, root common.Hash) string { return string(append(owner.Bytes(), root.Bytes()...)) } // subfetcher is a trie fetcher goroutine responsible for pulling entries for a // single trie. It is spawned when a new root is encountered and lives until the // main prefetcher is paused and either all requested items are processed or if // the trie being worked on is retrieved from the prefetcher. type subfetcher struct { db Database // Database to load trie nodes through state common.Hash // Root hash of the state to prefetch owner common.Hash // Owner of the trie, usually account hash root common.Hash // Root hash of the trie to prefetch trie Trie // Trie being populated with nodes tasks [][]byte // Items queued up for retrieval lock sync.Mutex // Lock protecting the task queue wake chan struct{} // Wake channel if a new task is scheduled stop chan struct{} // Channel to interrupt processing term chan struct{} // Channel to signal interruption copy chan chan Trie // Channel to request a copy of the current trie seen map[string]struct{} // Tracks the entries already loaded dups int // Number of duplicate preload tasks used [][]byte // Tracks the entries used in the end } // newSubfetcher creates a goroutine to prefetch state items belonging to a // particular root hash. func newSubfetcher(db Database, state common.Hash, owner common.Hash, root common.Hash) *subfetcher { sf := &subfetcher{ db: db, state: state, owner: owner, root: root, wake: make(chan struct{}, 1), stop: make(chan struct{}), term: make(chan struct{}), copy: make(chan chan Trie), seen: make(map[string]struct{}), } go sf.loop() return sf } // schedule adds a batch of trie keys to the queue to prefetch. func (sf *subfetcher) schedule(keys [][]byte) { // Append the tasks to the current queue sf.lock.Lock() sf.tasks = append(sf.tasks, keys...) sf.lock.Unlock() // Notify the prefetcher, it's fine if it's already terminated select { case sf.wake <- struct{}{}: default: } } // peek tries to retrieve a deep copy of the fetcher's trie in whatever form it // is currently. func (sf *subfetcher) peek() Trie { ch := make(chan Trie) select { case sf.copy <- ch: // Subfetcher still alive, return copy from it return <-ch case <-sf.term: // Subfetcher already terminated, return a copy directly if sf.trie == nil { return nil } return sf.db.CopyTrie(sf.trie) } } // abort interrupts the subfetcher immediately. It is safe to call abort multiple // times but it is not thread safe. func (sf *subfetcher) abort() { select { case <-sf.stop: default: close(sf.stop) } <-sf.term } // loop waits for new tasks to be scheduled and keeps loading them until it runs // out of tasks or its underlying trie is retrieved for committing. func (sf *subfetcher) loop() { // No matter how the loop stops, signal anyone waiting that it's terminated defer close(sf.term) // Start by opening the trie and stop processing if it fails if sf.owner == (common.Hash{}) { trie, err := sf.db.OpenTrie(sf.root) if err != nil { utils.Logger().Warn().Err(err).Interface("root", sf.root).Msg("Trie prefetcher failed opening trie") return } sf.trie = trie } else { trie, err := sf.db.OpenStorageTrie(sf.state, sf.owner, sf.root) if err != nil { utils.Logger().Warn().Err(err).Interface("root", sf.root).Msg("Trie prefetcher failed opening trie") return } sf.trie = trie } // Trie opened successfully, keep prefetching items for { select { case <-sf.wake: // Subfetcher was woken up, retrieve any tasks to avoid spinning the lock sf.lock.Lock() tasks := sf.tasks sf.tasks = nil sf.lock.Unlock() // Prefetch any tasks until the loop is interrupted for i, task := range tasks { select { case <-sf.stop: // If termination is requested, add any leftover back and return sf.lock.Lock() sf.tasks = append(sf.tasks, tasks[i:]...) sf.lock.Unlock() return case ch := <-sf.copy: // Somebody wants a copy of the current trie, grant them ch <- sf.db.CopyTrie(sf.trie) default: // No termination request yet, prefetch the next entry if _, ok := sf.seen[string(task)]; ok { sf.dups++ } else { sf.trie.TryGet(task) sf.seen[string(task)] = struct{}{} } } } case ch := <-sf.copy: // Somebody wants a copy of the current trie, grant them ch <- sf.db.CopyTrie(sf.trie) case <-sf.stop: // Termination is requested, abort and leave remaining tasks return } } }