// Copyright 2015 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 downloader contains the manual full chain synchronisation. package downloader import ( "errors" "fmt" "math/big" "sync" "sync/atomic" "time" ethereum "github.com/ethereum/go-ethereum" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/core/rawdb" "github.com/ethereum/go-ethereum/core/types" "github.com/ethereum/go-ethereum/ethdb" "github.com/ethereum/go-ethereum/event" "github.com/ethereum/go-ethereum/log" "github.com/ethereum/go-ethereum/metrics" "github.com/ethereum/go-ethereum/params" "github.com/ethereum/go-ethereum/trie" ) var ( MaxHashFetch = 512 // Amount of hashes to be fetched per retrieval request MaxBlockFetch = 128 // Amount of blocks to be fetched per retrieval request MaxHeaderFetch = 192 // Amount of block headers to be fetched per retrieval request MaxSkeletonSize = 128 // Number of header fetches to need for a skeleton assembly MaxBodyFetch = 128 // Amount of block bodies to be fetched per retrieval request MaxReceiptFetch = 256 // Amount of transaction receipts to allow fetching per request MaxStateFetch = 384 // Amount of node state values to allow fetching per request MaxForkAncestry = 3 * params.EpochDuration // Maximum chain reorganisation rttMinEstimate = 2 * time.Second // Minimum round-trip time to target for download requests rttMaxEstimate = 20 * time.Second // Maximum round-trip time to target for download requests rttMinConfidence = 0.1 // Worse confidence factor in our estimated RTT value ttlScaling = 3 // Constant scaling factor for RTT -> TTL conversion ttlLimit = time.Minute // Maximum TTL allowance to prevent reaching crazy timeouts qosTuningPeers = 5 // Number of peers to tune based on (best peers) qosConfidenceCap = 10 // Number of peers above which not to modify RTT confidence qosTuningImpact = 0.25 // Impact that a new tuning target has on the previous value maxQueuedHeaders = 32 * 1024 // [eth/62] Maximum number of headers to queue for import (DOS protection) maxHeadersProcess = 2048 // Number of header download results to import at once into the chain maxResultsProcess = 2048 // Number of content download results to import at once into the chain reorgProtThreshold = 48 // Threshold number of recent blocks to disable mini reorg protection reorgProtHeaderDelay = 2 // Number of headers to delay delivering to cover mini reorgs fsHeaderCheckFrequency = 100 // Verification frequency of the downloaded headers during fast sync fsHeaderSafetyNet = 2048 // Number of headers to discard in case a chain violation is detected fsHeaderForceVerify = 24 // Number of headers to verify before and after the pivot to accept it fsHeaderContCheck = 3 * time.Second // Time interval to check for header continuations during state download fsMinFullBlocks = 64 // Number of blocks to retrieve fully even in fast sync ) var ( errBusy = errors.New("busy") errUnknownPeer = errors.New("peer is unknown or unhealthy") errBadPeer = errors.New("action from bad peer ignored") errStallingPeer = errors.New("peer is stalling") errUnsyncedPeer = errors.New("unsynced peer") errNoPeers = errors.New("no peers to keep download active") errTimeout = errors.New("timeout") errEmptyHeaderSet = errors.New("empty header set by peer") errPeersUnavailable = errors.New("no peers available or all tried for download") errInvalidAncestor = errors.New("retrieved ancestor is invalid") errInvalidChain = errors.New("retrieved hash chain is invalid") errInvalidBlock = errors.New("retrieved block is invalid") errInvalidBody = errors.New("retrieved block body is invalid") errInvalidReceipt = errors.New("retrieved receipt is invalid") errCancelBlockFetch = errors.New("block download canceled (requested)") errCancelHeaderFetch = errors.New("block header download canceled (requested)") errCancelBodyFetch = errors.New("block body download canceled (requested)") errCancelReceiptFetch = errors.New("receipt download canceled (requested)") errCancelStateFetch = errors.New("state data download canceled (requested)") errCancelHeaderProcessing = errors.New("header processing canceled (requested)") errCancelContentProcessing = errors.New("content processing canceled (requested)") errNoSyncActive = errors.New("no sync active") errTooOld = errors.New("peer doesn't speak recent enough protocol version (need version >= 62)") ) type Downloader struct { mode SyncMode // Synchronisation mode defining the strategy used (per sync cycle) mux *event.TypeMux // Event multiplexer to announce sync operation events checkpoint uint64 // Checkpoint block number to enforce head against (e.g. fast sync) genesis uint64 // Genesis block number to limit sync to (e.g. light client CHT) queue *queue // Scheduler for selecting the hashes to download peers *peerSet // Set of active peers from which download can proceed stateDB ethdb.Database // Database to state sync into (and deduplicate via) stateBloom *trie.SyncBloom // Bloom filter for fast trie node existence checks rttEstimate uint64 // Round trip time to target for download requests rttConfidence uint64 // Confidence in the estimated RTT (unit: millionths to allow atomic ops) // Statistics syncStatsChainOrigin uint64 // Origin block number where syncing started at syncStatsChainHeight uint64 // Highest block number known when syncing started syncStatsState stateSyncStats syncStatsLock sync.RWMutex // Lock protecting the sync stats fields lightchain LightChain blockchain BlockChain // Callbacks dropPeer peerDropFn // Drops a peer for misbehaving // Status synchroniseMock func(id string, hash common.Hash) error // Replacement for synchronise during testing synchronising int32 notified int32 committed int32 ancientLimit uint64 // The maximum block number which can be regarded as ancient data. // Channels headerCh chan dataPack // [eth/62] Channel receiving inbound block headers bodyCh chan dataPack // [eth/62] Channel receiving inbound block bodies receiptCh chan dataPack // [eth/63] Channel receiving inbound receipts bodyWakeCh chan bool // [eth/62] Channel to signal the block body fetcher of new tasks receiptWakeCh chan bool // [eth/63] Channel to signal the receipt fetcher of new tasks headerProcCh chan []*types.Header // [eth/62] Channel to feed the header processor new tasks // for stateFetcher stateSyncStart chan *stateSync trackStateReq chan *stateReq stateCh chan dataPack // [eth/63] Channel receiving inbound node state data // Cancellation and termination cancelPeer string // Identifier of the peer currently being used as the master (cancel on drop) cancelCh chan struct{} // Channel to cancel mid-flight syncs cancelLock sync.RWMutex // Lock to protect the cancel channel and peer in delivers cancelWg sync.WaitGroup // Make sure all fetcher goroutines have exited. quitCh chan struct{} // Quit channel to signal termination quitLock sync.RWMutex // Lock to prevent double closes // Testing hooks syncInitHook func(uint64, uint64) // Method to call upon initiating a new sync run bodyFetchHook func([]*types.Header) // Method to call upon starting a block body fetch receiptFetchHook func([]*types.Header) // Method to call upon starting a receipt fetch chainInsertHook func([]*fetchResult) // Method to call upon inserting a chain of blocks (possibly in multiple invocations) } // LightChain encapsulates functions required to synchronise a light chain. type LightChain interface { // HasHeader verifies a header's presence in the local chain. HasHeader(common.Hash, uint64) bool // GetHeaderByHash retrieves a header from the local chain. GetHeaderByHash(common.Hash) *types.Header // CurrentHeader retrieves the head header from the local chain. CurrentHeader() *types.Header // GetTd returns the total difficulty of a local block. GetTd(common.Hash, uint64) *big.Int // InsertHeaderChain inserts a batch of headers into the local chain. InsertHeaderChain([]*types.Header, int) (int, error) // Rollback removes a few recently added elements from the local chain. Rollback([]common.Hash) } // BlockChain encapsulates functions required to sync a (full or fast) blockchain. type BlockChain interface { LightChain // HasBlock verifies a block's presence in the local chain. HasBlock(common.Hash, uint64) bool // HasFastBlock verifies a fast block's presence in the local chain. HasFastBlock(common.Hash, uint64) bool // GetBlockByHash retrieves a block from the local chain. GetBlockByHash(common.Hash) *types.Block // CurrentBlock retrieves the head block from the local chain. CurrentBlock() *types.Block // CurrentFastBlock retrieves the head fast block from the local chain. CurrentFastBlock() *types.Block // FastSyncCommitHead directly commits the head block to a certain entity. FastSyncCommitHead(common.Hash) error // InsertChain inserts a batch of blocks into the local chain. InsertChain(types.Blocks) (int, error) // InsertReceiptChain inserts a batch of receipts into the local chain. InsertReceiptChain(types.Blocks, []types.Receipts, uint64) (int, error) } // New creates a new downloader to fetch hashes and blocks from remote peers. func New(checkpoint uint64, stateDb ethdb.Database, stateBloom *trie.SyncBloom, mux *event.TypeMux, chain BlockChain, lightchain LightChain, dropPeer peerDropFn) *Downloader { if lightchain == nil { lightchain = chain } dl := &Downloader{ stateDB: stateDb, stateBloom: stateBloom, mux: mux, checkpoint: checkpoint, queue: newQueue(), peers: newPeerSet(), rttEstimate: uint64(rttMaxEstimate), rttConfidence: uint64(1000000), blockchain: chain, lightchain: lightchain, dropPeer: dropPeer, headerCh: make(chan dataPack, 1), bodyCh: make(chan dataPack, 1), receiptCh: make(chan dataPack, 1), bodyWakeCh: make(chan bool, 1), receiptWakeCh: make(chan bool, 1), headerProcCh: make(chan []*types.Header, 1), quitCh: make(chan struct{}), stateCh: make(chan dataPack), stateSyncStart: make(chan *stateSync), syncStatsState: stateSyncStats{ processed: rawdb.ReadFastTrieProgress(stateDb), }, trackStateReq: make(chan *stateReq), } go dl.qosTuner() go dl.stateFetcher() return dl } // Progress retrieves the synchronisation boundaries, specifically the origin // block where synchronisation started at (may have failed/suspended); the block // or header sync is currently at; and the latest known block which the sync targets. // // In addition, during the state download phase of fast synchronisation the number // of processed and the total number of known states are also returned. Otherwise // these are zero. func (d *Downloader) Progress() ethereum.SyncProgress { // Lock the current stats and return the progress d.syncStatsLock.RLock() defer d.syncStatsLock.RUnlock() current := uint64(0) switch { case d.blockchain != nil && d.mode == FullSync: current = d.blockchain.CurrentBlock().NumberU64() case d.blockchain != nil && d.mode == FastSync: current = d.blockchain.CurrentFastBlock().NumberU64() case d.lightchain != nil: current = d.lightchain.CurrentHeader().Number.Uint64() default: log.Error("Unknown downloader chain/mode combo", "light", d.lightchain != nil, "full", d.blockchain != nil, "mode", d.mode) } return ethereum.SyncProgress{ StartingBlock: d.syncStatsChainOrigin, CurrentBlock: current, HighestBlock: d.syncStatsChainHeight, PulledStates: d.syncStatsState.processed, KnownStates: d.syncStatsState.processed + d.syncStatsState.pending, } } // Synchronising returns whether the downloader is currently retrieving blocks. func (d *Downloader) Synchronising() bool { return atomic.LoadInt32(&d.synchronising) > 0 } // RegisterPeer injects a new download peer into the set of block source to be // used for fetching hashes and blocks from. func (d *Downloader) RegisterPeer(id string, version int, peer Peer) error { logger := log.New("peer", id) logger.Trace("Registering sync peer") if err := d.peers.Register(newPeerConnection(id, version, peer, logger)); err != nil { logger.Error("Failed to register sync peer", "err", err) return err } d.qosReduceConfidence() return nil } // RegisterLightPeer injects a light client peer, wrapping it so it appears as a regular peer. func (d *Downloader) RegisterLightPeer(id string, version int, peer LightPeer) error { return d.RegisterPeer(id, version, &lightPeerWrapper{peer}) } // UnregisterPeer remove a peer from the known list, preventing any action from // the specified peer. An effort is also made to return any pending fetches into // the queue. func (d *Downloader) UnregisterPeer(id string) error { // Unregister the peer from the active peer set and revoke any fetch tasks logger := log.New("peer", id) logger.Trace("Unregistering sync peer") if err := d.peers.Unregister(id); err != nil { logger.Error("Failed to unregister sync peer", "err", err) return err } d.queue.Revoke(id) // If this peer was the master peer, abort sync immediately d.cancelLock.RLock() master := id == d.cancelPeer d.cancelLock.RUnlock() if master { d.cancel() } return nil } // Synchronise tries to sync up our local block chain with a remote peer, both // adding various sanity checks as well as wrapping it with various log entries. func (d *Downloader) Synchronise(id string, head common.Hash, td *big.Int, mode SyncMode) error { err := d.synchronise(id, head, td, mode) switch err { case nil: case errBusy: case errTimeout, errBadPeer, errStallingPeer, errUnsyncedPeer, errEmptyHeaderSet, errPeersUnavailable, errTooOld, errInvalidAncestor, errInvalidChain: log.Warn("Synchronisation failed, dropping peer", "peer", id, "err", err) if d.dropPeer == nil { // The dropPeer method is nil when `--copydb` is used for a local copy. // Timeouts can occur if e.g. compaction hits at the wrong time, and can be ignored log.Warn("Downloader wants to drop peer, but peerdrop-function is not set", "peer", id) } else { d.dropPeer(id) } default: log.Warn("Synchronisation failed, retrying", "err", err) } return err } // synchronise will select the peer and use it for synchronising. If an empty string is given // it will use the best peer possible and synchronize if its TD is higher than our own. If any of the // checks fail an error will be returned. This method is synchronous func (d *Downloader) synchronise(id string, hash common.Hash, td *big.Int, mode SyncMode) error { // Mock out the synchronisation if testing if d.synchroniseMock != nil { return d.synchroniseMock(id, hash) } // Make sure only one goroutine is ever allowed past this point at once if !atomic.CompareAndSwapInt32(&d.synchronising, 0, 1) { return errBusy } defer atomic.StoreInt32(&d.synchronising, 0) // Post a user notification of the sync (only once per session) if atomic.CompareAndSwapInt32(&d.notified, 0, 1) { log.Info("Block synchronisation started") } // If we are already full syncing, but have a fast-sync bloom filter laying // around, make sure it does't use memory any more. This is a special case // when the user attempts to fast sync a new empty network. if mode == FullSync && d.stateBloom != nil { d.stateBloom.Close() } // Reset the queue, peer set and wake channels to clean any internal leftover state d.queue.Reset() d.peers.Reset() for _, ch := range []chan bool{d.bodyWakeCh, d.receiptWakeCh} { select { case <-ch: default: } } for _, ch := range []chan dataPack{d.headerCh, d.bodyCh, d.receiptCh} { for empty := false; !empty; { select { case <-ch: default: empty = true } } } for empty := false; !empty; { select { case <-d.headerProcCh: default: empty = true } } // Create cancel channel for aborting mid-flight and mark the master peer d.cancelLock.Lock() d.cancelCh = make(chan struct{}) d.cancelPeer = id d.cancelLock.Unlock() defer d.Cancel() // No matter what, we can't leave the cancel channel open // Set the requested sync mode, unless it's forbidden d.mode = mode // Retrieve the origin peer and initiate the downloading process p := d.peers.Peer(id) if p == nil { return errUnknownPeer } return d.syncWithPeer(p, hash, td) } // syncWithPeer starts a block synchronization based on the hash chain from the // specified peer and head hash. func (d *Downloader) syncWithPeer(p *peerConnection, hash common.Hash, td *big.Int) (err error) { d.mux.Post(StartEvent{}) defer func() { // reset on error if err != nil { d.mux.Post(FailedEvent{err}) } else { latest := d.lightchain.CurrentHeader() d.mux.Post(DoneEvent{latest}) } }() if p.version < 62 { return errTooOld } log.Debug("Synchronising with the network", "peer", p.id, "eth", p.version, "head", hash, "td", td, "mode", d.mode) defer func(start time.Time) { log.Debug("Synchronisation terminated", "elapsed", time.Since(start)) }(time.Now()) // Look up the sync boundaries: the common ancestor and the target block latest, err := d.fetchHeight(p) if err != nil { return err } height := latest.Number.Uint64() origin, err := d.findAncestor(p, latest) if err != nil { return err } d.syncStatsLock.Lock() if d.syncStatsChainHeight <= origin || d.syncStatsChainOrigin > origin { d.syncStatsChainOrigin = origin } d.syncStatsChainHeight = height d.syncStatsLock.Unlock() // Ensure our origin point is below any fast sync pivot point pivot := uint64(0) if d.mode == FastSync { if height <= uint64(fsMinFullBlocks) { origin = 0 } else { pivot = height - uint64(fsMinFullBlocks) if pivot <= origin { origin = pivot - 1 } } } d.committed = 1 if d.mode == FastSync && pivot != 0 { d.committed = 0 } if d.mode == FastSync { // Set the ancient data limitation. // If we are running fast sync, all block data older than ancientLimit will be // written to the ancient store. More recent data will be written to the active // database and will wait for the freezer to migrate. // // If there is a checkpoint available, then calculate the ancientLimit through // that. Otherwise calculate the ancient limit through the advertised height // of the remote peer. // // The reason for picking checkpoint first is that a malicious peer can give us // a fake (very high) height, forcing the ancient limit to also be very high. // The peer would start to feed us valid blocks until head, resulting in all of // the blocks might be written into the ancient store. A following mini-reorg // could cause issues. if d.checkpoint != 0 && d.checkpoint > MaxForkAncestry+1 { d.ancientLimit = d.checkpoint } else if height > MaxForkAncestry+1 { d.ancientLimit = height - MaxForkAncestry - 1 } frozen, _ := d.stateDB.Ancients() // Ignore the error here since light client can also hit here. // If a part of blockchain data has already been written into active store, // disable the ancient style insertion explicitly. if origin >= frozen && frozen != 0 { d.ancientLimit = 0 log.Info("Disabling direct-ancient mode", "origin", origin, "ancient", frozen-1) } else if d.ancientLimit > 0 { log.Debug("Enabling direct-ancient mode", "ancient", d.ancientLimit) } // Rewind the ancient store and blockchain if reorg happens. if origin+1 < frozen { var hashes []common.Hash for i := origin + 1; i < d.lightchain.CurrentHeader().Number.Uint64(); i++ { hashes = append(hashes, rawdb.ReadCanonicalHash(d.stateDB, i)) } d.lightchain.Rollback(hashes) } } // Initiate the sync using a concurrent header and content retrieval algorithm d.queue.Prepare(origin+1, d.mode) if d.syncInitHook != nil { d.syncInitHook(origin, height) } fetchers := []func() error{ func() error { return d.fetchHeaders(p, origin+1, pivot) }, // Headers are always retrieved func() error { return d.fetchBodies(origin + 1) }, // Bodies are retrieved during normal and fast sync func() error { return d.fetchReceipts(origin + 1) }, // Receipts are retrieved during fast sync func() error { return d.processHeaders(origin+1, pivot, td) }, } if d.mode == FastSync { fetchers = append(fetchers, func() error { return d.processFastSyncContent(latest) }) } else if d.mode == FullSync { fetchers = append(fetchers, d.processFullSyncContent) } return d.spawnSync(fetchers) } // spawnSync runs d.process and all given fetcher functions to completion in // separate goroutines, returning the first error that appears. func (d *Downloader) spawnSync(fetchers []func() error) error { errc := make(chan error, len(fetchers)) d.cancelWg.Add(len(fetchers)) for _, fn := range fetchers { fn := fn go func() { defer d.cancelWg.Done(); errc <- fn() }() } // Wait for the first error, then terminate the others. var err error for i := 0; i < len(fetchers); i++ { if i == len(fetchers)-1 { // Close the queue when all fetchers have exited. // This will cause the block processor to end when // it has processed the queue. d.queue.Close() } if err = <-errc; err != nil { break } } d.queue.Close() d.Cancel() return err } // cancel aborts all of the operations and resets the queue. However, cancel does // not wait for the running download goroutines to finish. This method should be // used when cancelling the downloads from inside the downloader. func (d *Downloader) cancel() { // Close the current cancel channel d.cancelLock.Lock() if d.cancelCh != nil { select { case <-d.cancelCh: // Channel was already closed default: close(d.cancelCh) } } d.cancelLock.Unlock() } // Cancel aborts all of the operations and waits for all download goroutines to // finish before returning. func (d *Downloader) Cancel() { d.cancel() d.cancelWg.Wait() d.ancientLimit = 0 log.Debug("Reset ancient limit to zero") } // Terminate interrupts the downloader, canceling all pending operations. // The downloader cannot be reused after calling Terminate. func (d *Downloader) Terminate() { // Close the termination channel (make sure double close is allowed) d.quitLock.Lock() select { case <-d.quitCh: default: close(d.quitCh) } d.quitLock.Unlock() // Cancel any pending download requests d.Cancel() } // fetchHeight retrieves the head header of the remote peer to aid in estimating // the total time a pending synchronisation would take. func (d *Downloader) fetchHeight(p *peerConnection) (*types.Header, error) { p.log.Debug("Retrieving remote chain height") // Request the advertised remote head block and wait for the response head, _ := p.peer.Head() go p.peer.RequestHeadersByHash(head, 1, 0, false) ttl := d.requestTTL() timeout := time.After(ttl) for { select { case <-d.cancelCh: return nil, errCancelBlockFetch case packet := <-d.headerCh: // Discard anything not from the origin peer if packet.PeerId() != p.id { log.Debug("Received headers from incorrect peer", "peer", packet.PeerId()) break } // Make sure the peer actually gave something valid headers := packet.(*headerPack).headers if len(headers) != 1 { p.log.Debug("Multiple headers for single request", "headers", len(headers)) return nil, errBadPeer } head := headers[0] if (d.mode == FastSync || d.mode == LightSync) && head.Number.Uint64() < d.checkpoint { p.log.Warn("Remote head below checkpoint", "number", head.Number, "hash", head.Hash()) return nil, errUnsyncedPeer } p.log.Debug("Remote head header identified", "number", head.Number, "hash", head.Hash()) return head, nil case <-timeout: p.log.Debug("Waiting for head header timed out", "elapsed", ttl) return nil, errTimeout case <-d.bodyCh: case <-d.receiptCh: // Out of bounds delivery, ignore } } } // calculateRequestSpan calculates what headers to request from a peer when trying to determine the // common ancestor. // It returns parameters to be used for peer.RequestHeadersByNumber: // from - starting block number // count - number of headers to request // skip - number of headers to skip // and also returns 'max', the last block which is expected to be returned by the remote peers, // given the (from,count,skip) func calculateRequestSpan(remoteHeight, localHeight uint64) (int64, int, int, uint64) { var ( from int count int MaxCount = MaxHeaderFetch / 16 ) // requestHead is the highest block that we will ask for. If requestHead is not offset, // the highest block that we will get is 16 blocks back from head, which means we // will fetch 14 or 15 blocks unnecessarily in the case the height difference // between us and the peer is 1-2 blocks, which is most common requestHead := int(remoteHeight) - 1 if requestHead < 0 { requestHead = 0 } // requestBottom is the lowest block we want included in the query // Ideally, we want to include just below own head requestBottom := int(localHeight - 1) if requestBottom < 0 { requestBottom = 0 } totalSpan := requestHead - requestBottom span := 1 + totalSpan/MaxCount if span < 2 { span = 2 } if span > 16 { span = 16 } count = 1 + totalSpan/span if count > MaxCount { count = MaxCount } if count < 2 { count = 2 } from = requestHead - (count-1)*span if from < 0 { from = 0 } max := from + (count-1)*span return int64(from), count, span - 1, uint64(max) } // findAncestor tries to locate the common ancestor link of the local chain and // a remote peers blockchain. In the general case when our node was in sync and // on the correct chain, checking the top N links should already get us a match. // In the rare scenario when we ended up on a long reorganisation (i.e. none of // the head links match), we do a binary search to find the common ancestor. func (d *Downloader) findAncestor(p *peerConnection, remoteHeader *types.Header) (uint64, error) { // Figure out the valid ancestor range to prevent rewrite attacks var ( floor = int64(-1) localHeight uint64 remoteHeight = remoteHeader.Number.Uint64() ) switch d.mode { case FullSync: localHeight = d.blockchain.CurrentBlock().NumberU64() case FastSync: localHeight = d.blockchain.CurrentFastBlock().NumberU64() default: localHeight = d.lightchain.CurrentHeader().Number.Uint64() } p.log.Debug("Looking for common ancestor", "local", localHeight, "remote", remoteHeight) // Recap floor value for binary search if localHeight >= MaxForkAncestry { // We're above the max reorg threshold, find the earliest fork point floor = int64(localHeight - MaxForkAncestry) } // If we're doing a light sync, ensure the floor doesn't go below the CHT, as // all headers before that point will be missing. if d.mode == LightSync { // If we dont know the current CHT position, find it if d.genesis == 0 { header := d.lightchain.CurrentHeader() for header != nil { d.genesis = header.Number.Uint64() if floor >= int64(d.genesis)-1 { break } header = d.lightchain.GetHeaderByHash(header.ParentHash) } } // We already know the "genesis" block number, cap floor to that if floor < int64(d.genesis)-1 { floor = int64(d.genesis) - 1 } } from, count, skip, max := calculateRequestSpan(remoteHeight, localHeight) p.log.Trace("Span searching for common ancestor", "count", count, "from", from, "skip", skip) go p.peer.RequestHeadersByNumber(uint64(from), count, skip, false) // Wait for the remote response to the head fetch number, hash := uint64(0), common.Hash{} ttl := d.requestTTL() timeout := time.After(ttl) for finished := false; !finished; { select { case <-d.cancelCh: return 0, errCancelHeaderFetch case packet := <-d.headerCh: // Discard anything not from the origin peer if packet.PeerId() != p.id { log.Debug("Received headers from incorrect peer", "peer", packet.PeerId()) break } // Make sure the peer actually gave something valid headers := packet.(*headerPack).headers if len(headers) == 0 { p.log.Warn("Empty head header set") return 0, errEmptyHeaderSet } // Make sure the peer's reply conforms to the request for i, header := range headers { expectNumber := from + int64(i)*int64(skip+1) if number := header.Number.Int64(); number != expectNumber { p.log.Warn("Head headers broke chain ordering", "index", i, "requested", expectNumber, "received", number) return 0, errInvalidChain } } // Check if a common ancestor was found finished = true for i := len(headers) - 1; i >= 0; i-- { // Skip any headers that underflow/overflow our requested set if headers[i].Number.Int64() < from || headers[i].Number.Uint64() > max { continue } // Otherwise check if we already know the header or not h := headers[i].Hash() n := headers[i].Number.Uint64() var known bool switch d.mode { case FullSync: known = d.blockchain.HasBlock(h, n) case FastSync: known = d.blockchain.HasFastBlock(h, n) default: known = d.lightchain.HasHeader(h, n) } if known { number, hash = n, h break } } case <-timeout: p.log.Debug("Waiting for head header timed out", "elapsed", ttl) return 0, errTimeout case <-d.bodyCh: case <-d.receiptCh: // Out of bounds delivery, ignore } } // If the head fetch already found an ancestor, return if hash != (common.Hash{}) { if int64(number) <= floor { p.log.Warn("Ancestor below allowance", "number", number, "hash", hash, "allowance", floor) return 0, errInvalidAncestor } p.log.Debug("Found common ancestor", "number", number, "hash", hash) return number, nil } // Ancestor not found, we need to binary search over our chain start, end := uint64(0), remoteHeight if floor > 0 { start = uint64(floor) } p.log.Trace("Binary searching for common ancestor", "start", start, "end", end) for start+1 < end { // Split our chain interval in two, and request the hash to cross check check := (start + end) / 2 ttl := d.requestTTL() timeout := time.After(ttl) go p.peer.RequestHeadersByNumber(check, 1, 0, false) // Wait until a reply arrives to this request for arrived := false; !arrived; { select { case <-d.cancelCh: return 0, errCancelHeaderFetch case packer := <-d.headerCh: // Discard anything not from the origin peer if packer.PeerId() != p.id { log.Debug("Received headers from incorrect peer", "peer", packer.PeerId()) break } // Make sure the peer actually gave something valid headers := packer.(*headerPack).headers if len(headers) != 1 { p.log.Debug("Multiple headers for single request", "headers", len(headers)) return 0, errBadPeer } arrived = true // Modify the search interval based on the response h := headers[0].Hash() n := headers[0].Number.Uint64() var known bool switch d.mode { case FullSync: known = d.blockchain.HasBlock(h, n) case FastSync: known = d.blockchain.HasFastBlock(h, n) default: known = d.lightchain.HasHeader(h, n) } if !known { end = check break } header := d.lightchain.GetHeaderByHash(h) // Independent of sync mode, header surely exists if header.Number.Uint64() != check { p.log.Debug("Received non requested header", "number", header.Number, "hash", header.Hash(), "request", check) return 0, errBadPeer } start = check hash = h case <-timeout: p.log.Debug("Waiting for search header timed out", "elapsed", ttl) return 0, errTimeout case <-d.bodyCh: case <-d.receiptCh: // Out of bounds delivery, ignore } } } // Ensure valid ancestry and return if int64(start) <= floor { p.log.Warn("Ancestor below allowance", "number", start, "hash", hash, "allowance", floor) return 0, errInvalidAncestor } p.log.Debug("Found common ancestor", "number", start, "hash", hash) return start, nil } // fetchHeaders keeps retrieving headers concurrently from the number // requested, until no more are returned, potentially throttling on the way. To // facilitate concurrency but still protect against malicious nodes sending bad // headers, we construct a header chain skeleton using the "origin" peer we are // syncing with, and fill in the missing headers using anyone else. Headers from // other peers are only accepted if they map cleanly to the skeleton. If no one // can fill in the skeleton - not even the origin peer - it's assumed invalid and // the origin is dropped. func (d *Downloader) fetchHeaders(p *peerConnection, from uint64, pivot uint64) error { p.log.Debug("Directing header downloads", "origin", from) defer p.log.Debug("Header download terminated") // Create a timeout timer, and the associated header fetcher skeleton := true // Skeleton assembly phase or finishing up request := time.Now() // time of the last skeleton fetch request timeout := time.NewTimer(0) // timer to dump a non-responsive active peer <-timeout.C // timeout channel should be initially empty defer timeout.Stop() var ttl time.Duration getHeaders := func(from uint64) { request = time.Now() ttl = d.requestTTL() timeout.Reset(ttl) if skeleton { p.log.Trace("Fetching skeleton headers", "count", MaxHeaderFetch, "from", from) go p.peer.RequestHeadersByNumber(from+uint64(MaxHeaderFetch)-1, MaxSkeletonSize, MaxHeaderFetch-1, false) } else { p.log.Trace("Fetching full headers", "count", MaxHeaderFetch, "from", from) go p.peer.RequestHeadersByNumber(from, MaxHeaderFetch, 0, false) } } // Start pulling the header chain skeleton until all is done ancestor := from getHeaders(from) for { select { case <-d.cancelCh: return errCancelHeaderFetch case packet := <-d.headerCh: // Make sure the active peer is giving us the skeleton headers if packet.PeerId() != p.id { log.Debug("Received skeleton from incorrect peer", "peer", packet.PeerId()) break } headerReqTimer.UpdateSince(request) timeout.Stop() // If the skeleton's finished, pull any remaining head headers directly from the origin if packet.Items() == 0 && skeleton { skeleton = false getHeaders(from) continue } // If no more headers are inbound, notify the content fetchers and return if packet.Items() == 0 { // Don't abort header fetches while the pivot is downloading if atomic.LoadInt32(&d.committed) == 0 && pivot <= from { p.log.Debug("No headers, waiting for pivot commit") select { case <-time.After(fsHeaderContCheck): getHeaders(from) continue case <-d.cancelCh: return errCancelHeaderFetch } } // Pivot done (or not in fast sync) and no more headers, terminate the process p.log.Debug("No more headers available") select { case d.headerProcCh <- nil: return nil case <-d.cancelCh: return errCancelHeaderFetch } } headers := packet.(*headerPack).headers // If we received a skeleton batch, resolve internals concurrently if skeleton { filled, proced, err := d.fillHeaderSkeleton(from, headers) if err != nil { p.log.Debug("Skeleton chain invalid", "err", err) return errInvalidChain } headers = filled[proced:] from += uint64(proced) } else { // If we're closing in on the chain head, but haven't yet reached it, delay // the last few headers so mini reorgs on the head don't cause invalid hash // chain errors. if n := len(headers); n > 0 { // Retrieve the current head we're at head := uint64(0) if d.mode == LightSync { head = d.lightchain.CurrentHeader().Number.Uint64() } else { head = d.blockchain.CurrentFastBlock().NumberU64() if full := d.blockchain.CurrentBlock().NumberU64(); head < full { head = full } } // If the head is below the common ancestor, we're actually deduplicating // already existing chain segments, so use the ancestor as the fake head. // Otherwise we might end up delaying header deliveries pointlessly. if head < ancestor { head = ancestor } // If the head is way older than this batch, delay the last few headers if head+uint64(reorgProtThreshold) < headers[n-1].Number.Uint64() { delay := reorgProtHeaderDelay if delay > n { delay = n } headers = headers[:n-delay] } } } // Insert all the new headers and fetch the next batch if len(headers) > 0 { p.log.Trace("Scheduling new headers", "count", len(headers), "from", from) select { case d.headerProcCh <- headers: case <-d.cancelCh: return errCancelHeaderFetch } from += uint64(len(headers)) getHeaders(from) } else { // No headers delivered, or all of them being delayed, sleep a bit and retry p.log.Trace("All headers delayed, waiting") select { case <-time.After(fsHeaderContCheck): getHeaders(from) continue case <-d.cancelCh: return errCancelHeaderFetch } } case <-timeout.C: if d.dropPeer == nil { // The dropPeer method is nil when `--copydb` is used for a local copy. // Timeouts can occur if e.g. compaction hits at the wrong time, and can be ignored p.log.Warn("Downloader wants to drop peer, but peerdrop-function is not set", "peer", p.id) break } // Header retrieval timed out, consider the peer bad and drop p.log.Debug("Header request timed out", "elapsed", ttl) headerTimeoutMeter.Mark(1) d.dropPeer(p.id) // Finish the sync gracefully instead of dumping the gathered data though for _, ch := range []chan bool{d.bodyWakeCh, d.receiptWakeCh} { select { case ch <- false: case <-d.cancelCh: } } select { case d.headerProcCh <- nil: case <-d.cancelCh: } return errBadPeer } } } // fillHeaderSkeleton concurrently retrieves headers from all our available peers // and maps them to the provided skeleton header chain. // // Any partial results from the beginning of the skeleton is (if possible) forwarded // immediately to the header processor to keep the rest of the pipeline full even // in the case of header stalls. // // The method returns the entire filled skeleton and also the number of headers // already forwarded for processing. func (d *Downloader) fillHeaderSkeleton(from uint64, skeleton []*types.Header) ([]*types.Header, int, error) { log.Debug("Filling up skeleton", "from", from) d.queue.ScheduleSkeleton(from, skeleton) var ( deliver = func(packet dataPack) (int, error) { pack := packet.(*headerPack) return d.queue.DeliverHeaders(pack.peerID, pack.headers, d.headerProcCh) } expire = func() map[string]int { return d.queue.ExpireHeaders(d.requestTTL()) } throttle = func() bool { return false } reserve = func(p *peerConnection, count int) (*fetchRequest, bool, error) { return d.queue.ReserveHeaders(p, count), false, nil } fetch = func(p *peerConnection, req *fetchRequest) error { return p.FetchHeaders(req.From, MaxHeaderFetch) } capacity = func(p *peerConnection) int { return p.HeaderCapacity(d.requestRTT()) } setIdle = func(p *peerConnection, accepted int) { p.SetHeadersIdle(accepted) } ) err := d.fetchParts(errCancelHeaderFetch, d.headerCh, deliver, d.queue.headerContCh, expire, d.queue.PendingHeaders, d.queue.InFlightHeaders, throttle, reserve, nil, fetch, d.queue.CancelHeaders, capacity, d.peers.HeaderIdlePeers, setIdle, "headers") log.Debug("Skeleton fill terminated", "err", err) filled, proced := d.queue.RetrieveHeaders() return filled, proced, err } // fetchBodies iteratively downloads the scheduled block bodies, taking any // available peers, reserving a chunk of blocks for each, waiting for delivery // and also periodically checking for timeouts. func (d *Downloader) fetchBodies(from uint64) error { log.Debug("Downloading block bodies", "origin", from) var ( deliver = func(packet dataPack) (int, error) { pack := packet.(*bodyPack) return d.queue.DeliverBodies(pack.peerID, pack.transactions, pack.uncles) } expire = func() map[string]int { return d.queue.ExpireBodies(d.requestTTL()) } fetch = func(p *peerConnection, req *fetchRequest) error { return p.FetchBodies(req) } capacity = func(p *peerConnection) int { return p.BlockCapacity(d.requestRTT()) } setIdle = func(p *peerConnection, accepted int) { p.SetBodiesIdle(accepted) } ) err := d.fetchParts(errCancelBodyFetch, d.bodyCh, deliver, d.bodyWakeCh, expire, d.queue.PendingBlocks, d.queue.InFlightBlocks, d.queue.ShouldThrottleBlocks, d.queue.ReserveBodies, d.bodyFetchHook, fetch, d.queue.CancelBodies, capacity, d.peers.BodyIdlePeers, setIdle, "bodies") log.Debug("Block body download terminated", "err", err) return err } // fetchReceipts iteratively downloads the scheduled block receipts, taking any // available peers, reserving a chunk of receipts for each, waiting for delivery // and also periodically checking for timeouts. func (d *Downloader) fetchReceipts(from uint64) error { log.Debug("Downloading transaction receipts", "origin", from) var ( deliver = func(packet dataPack) (int, error) { pack := packet.(*receiptPack) return d.queue.DeliverReceipts(pack.peerID, pack.receipts) } expire = func() map[string]int { return d.queue.ExpireReceipts(d.requestTTL()) } fetch = func(p *peerConnection, req *fetchRequest) error { return p.FetchReceipts(req) } capacity = func(p *peerConnection) int { return p.ReceiptCapacity(d.requestRTT()) } setIdle = func(p *peerConnection, accepted int) { p.SetReceiptsIdle(accepted) } ) err := d.fetchParts(errCancelReceiptFetch, d.receiptCh, deliver, d.receiptWakeCh, expire, d.queue.PendingReceipts, d.queue.InFlightReceipts, d.queue.ShouldThrottleReceipts, d.queue.ReserveReceipts, d.receiptFetchHook, fetch, d.queue.CancelReceipts, capacity, d.peers.ReceiptIdlePeers, setIdle, "receipts") log.Debug("Transaction receipt download terminated", "err", err) return err } // fetchParts iteratively downloads scheduled block parts, taking any available // peers, reserving a chunk of fetch requests for each, waiting for delivery and // also periodically checking for timeouts. // // As the scheduling/timeout logic mostly is the same for all downloaded data // types, this method is used by each for data gathering and is instrumented with // various callbacks to handle the slight differences between processing them. // // The instrumentation parameters: // - errCancel: error type to return if the fetch operation is cancelled (mostly makes logging nicer) // - deliveryCh: channel from which to retrieve downloaded data packets (merged from all concurrent peers) // - deliver: processing callback to deliver data packets into type specific download queues (usually within `queue`) // - wakeCh: notification channel for waking the fetcher when new tasks are available (or sync completed) // - expire: task callback method to abort requests that took too long and return the faulty peers (traffic shaping) // - pending: task callback for the number of requests still needing download (detect completion/non-completability) // - inFlight: task callback for the number of in-progress requests (wait for all active downloads to finish) // - throttle: task callback to check if the processing queue is full and activate throttling (bound memory use) // - reserve: task callback to reserve new download tasks to a particular peer (also signals partial completions) // - fetchHook: tester callback to notify of new tasks being initiated (allows testing the scheduling logic) // - fetch: network callback to actually send a particular download request to a physical remote peer // - cancel: task callback to abort an in-flight download request and allow rescheduling it (in case of lost peer) // - capacity: network callback to retrieve the estimated type-specific bandwidth capacity of a peer (traffic shaping) // - idle: network callback to retrieve the currently (type specific) idle peers that can be assigned tasks // - setIdle: network callback to set a peer back to idle and update its estimated capacity (traffic shaping) // - kind: textual label of the type being downloaded to display in log mesages func (d *Downloader) fetchParts(errCancel error, deliveryCh chan dataPack, deliver func(dataPack) (int, error), wakeCh chan bool, expire func() map[string]int, pending func() int, inFlight func() bool, throttle func() bool, reserve func(*peerConnection, int) (*fetchRequest, bool, error), fetchHook func([]*types.Header), fetch func(*peerConnection, *fetchRequest) error, cancel func(*fetchRequest), capacity func(*peerConnection) int, idle func() ([]*peerConnection, int), setIdle func(*peerConnection, int), kind string) error { // Create a ticker to detect expired retrieval tasks ticker := time.NewTicker(100 * time.Millisecond) defer ticker.Stop() update := make(chan struct{}, 1) // Prepare the queue and fetch block parts until the block header fetcher's done finished := false for { select { case <-d.cancelCh: return errCancel case packet := <-deliveryCh: // If the peer was previously banned and failed to deliver its pack // in a reasonable time frame, ignore its message. if peer := d.peers.Peer(packet.PeerId()); peer != nil { // Deliver the received chunk of data and check chain validity accepted, err := deliver(packet) if err == errInvalidChain { return err } // Unless a peer delivered something completely else than requested (usually // caused by a timed out request which came through in the end), set it to // idle. If the delivery's stale, the peer should have already been idled. if err != errStaleDelivery { setIdle(peer, accepted) } // Issue a log to the user to see what's going on switch { case err == nil && packet.Items() == 0: peer.log.Trace("Requested data not delivered", "type", kind) case err == nil: peer.log.Trace("Delivered new batch of data", "type", kind, "count", packet.Stats()) default: peer.log.Trace("Failed to deliver retrieved data", "type", kind, "err", err) } } // Blocks assembled, try to update the progress select { case update <- struct{}{}: default: } case cont := <-wakeCh: // The header fetcher sent a continuation flag, check if it's done if !cont { finished = true } // Headers arrive, try to update the progress select { case update <- struct{}{}: default: } case <-ticker.C: // Sanity check update the progress select { case update <- struct{}{}: default: } case <-update: // Short circuit if we lost all our peers if d.peers.Len() == 0 { return errNoPeers } // Check for fetch request timeouts and demote the responsible peers for pid, fails := range expire() { if peer := d.peers.Peer(pid); peer != nil { // If a lot of retrieval elements expired, we might have overestimated the remote peer or perhaps // ourselves. Only reset to minimal throughput but don't drop just yet. If even the minimal times // out that sync wise we need to get rid of the peer. // // The reason the minimum threshold is 2 is because the downloader tries to estimate the bandwidth // and latency of a peer separately, which requires pushing the measures capacity a bit and seeing // how response times reacts, to it always requests one more than the minimum (i.e. min 2). if fails > 2 { peer.log.Trace("Data delivery timed out", "type", kind) setIdle(peer, 0) } else { peer.log.Debug("Stalling delivery, dropping", "type", kind) if d.dropPeer == nil { // The dropPeer method is nil when `--copydb` is used for a local copy. // Timeouts can occur if e.g. compaction hits at the wrong time, and can be ignored peer.log.Warn("Downloader wants to drop peer, but peerdrop-function is not set", "peer", pid) } else { d.dropPeer(pid) } } } } // If there's nothing more to fetch, wait or terminate if pending() == 0 { if !inFlight() && finished { log.Debug("Data fetching completed", "type", kind) return nil } break } // Send a download request to all idle peers, until throttled progressed, throttled, running := false, false, inFlight() idles, total := idle() for _, peer := range idles { // Short circuit if throttling activated if throttle() { throttled = true break } // Short circuit if there is no more available task. if pending() == 0 { break } // Reserve a chunk of fetches for a peer. A nil can mean either that // no more headers are available, or that the peer is known not to // have them. request, progress, err := reserve(peer, capacity(peer)) if err != nil { return err } if progress { progressed = true } if request == nil { continue } if request.From > 0 { peer.log.Trace("Requesting new batch of data", "type", kind, "from", request.From) } else { peer.log.Trace("Requesting new batch of data", "type", kind, "count", len(request.Headers), "from", request.Headers[0].Number) } // Fetch the chunk and make sure any errors return the hashes to the queue if fetchHook != nil { fetchHook(request.Headers) } if err := fetch(peer, request); err != nil { // Although we could try and make an attempt to fix this, this error really // means that we've double allocated a fetch task to a peer. If that is the // case, the internal state of the downloader and the queue is very wrong so // better hard crash and note the error instead of silently accumulating into // a much bigger issue. panic(fmt.Sprintf("%v: %s fetch assignment failed", peer, kind)) } running = true } // Make sure that we have peers available for fetching. If all peers have been tried // and all failed throw an error if !progressed && !throttled && !running && len(idles) == total && pending() > 0 { return errPeersUnavailable } } } } // processHeaders takes batches of retrieved headers from an input channel and // keeps processing and scheduling them into the header chain and downloader's // queue until the stream ends or a failure occurs. func (d *Downloader) processHeaders(origin uint64, pivot uint64, td *big.Int) error { // Keep a count of uncertain headers to roll back var rollback []*types.Header defer func() { if len(rollback) > 0 { // Flatten the headers and roll them back hashes := make([]common.Hash, len(rollback)) for i, header := range rollback { hashes[i] = header.Hash() } lastHeader, lastFastBlock, lastBlock := d.lightchain.CurrentHeader().Number, common.Big0, common.Big0 if d.mode != LightSync { lastFastBlock = d.blockchain.CurrentFastBlock().Number() lastBlock = d.blockchain.CurrentBlock().Number() } d.lightchain.Rollback(hashes) curFastBlock, curBlock := common.Big0, common.Big0 if d.mode != LightSync { curFastBlock = d.blockchain.CurrentFastBlock().Number() curBlock = d.blockchain.CurrentBlock().Number() } log.Warn("Rolled back headers", "count", len(hashes), "header", fmt.Sprintf("%d->%d", lastHeader, d.lightchain.CurrentHeader().Number), "fast", fmt.Sprintf("%d->%d", lastFastBlock, curFastBlock), "block", fmt.Sprintf("%d->%d", lastBlock, curBlock)) } }() // Wait for batches of headers to process gotHeaders := false for { select { case <-d.cancelCh: return errCancelHeaderProcessing case headers := <-d.headerProcCh: // Terminate header processing if we synced up if len(headers) == 0 { // Notify everyone that headers are fully processed for _, ch := range []chan bool{d.bodyWakeCh, d.receiptWakeCh} { select { case ch <- false: case <-d.cancelCh: } } // If no headers were retrieved at all, the peer violated its TD promise that it had a // better chain compared to ours. The only exception is if its promised blocks were // already imported by other means (e.g. fetcher): // // R , L : Both at block 10 // R: Mine block 11, and propagate it to L // L: Queue block 11 for import // L: Notice that R's head and TD increased compared to ours, start sync // L: Import of block 11 finishes // L: Sync begins, and finds common ancestor at 11 // L: Request new headers up from 11 (R's TD was higher, it must have something) // R: Nothing to give if d.mode != LightSync { head := d.blockchain.CurrentBlock() if !gotHeaders && td.Cmp(d.blockchain.GetTd(head.Hash(), head.NumberU64())) > 0 { return errStallingPeer } } // If fast or light syncing, ensure promised headers are indeed delivered. This is // needed to detect scenarios where an attacker feeds a bad pivot and then bails out // of delivering the post-pivot blocks that would flag the invalid content. // // This check cannot be executed "as is" for full imports, since blocks may still be // queued for processing when the header download completes. However, as long as the // peer gave us something useful, we're already happy/progressed (above check). if d.mode == FastSync || d.mode == LightSync { head := d.lightchain.CurrentHeader() if td.Cmp(d.lightchain.GetTd(head.Hash(), head.Number.Uint64())) > 0 { return errStallingPeer } } // Disable any rollback and return rollback = nil return nil } // Otherwise split the chunk of headers into batches and process them gotHeaders = true for len(headers) > 0 { // Terminate if something failed in between processing chunks select { case <-d.cancelCh: return errCancelHeaderProcessing default: } // Select the next chunk of headers to import limit := maxHeadersProcess if limit > len(headers) { limit = len(headers) } chunk := headers[:limit] // In case of header only syncing, validate the chunk immediately if d.mode == FastSync || d.mode == LightSync { // Collect the yet unknown headers to mark them as uncertain unknown := make([]*types.Header, 0, len(chunk)) for _, header := range chunk { if !d.lightchain.HasHeader(header.Hash(), header.Number.Uint64()) { unknown = append(unknown, header) } } // If we're importing pure headers, verify based on their recentness frequency := fsHeaderCheckFrequency if chunk[len(chunk)-1].Number.Uint64()+uint64(fsHeaderForceVerify) > pivot { frequency = 1 } if n, err := d.lightchain.InsertHeaderChain(chunk, frequency); err != nil { // If some headers were inserted, add them too to the rollback list if n > 0 { rollback = append(rollback, chunk[:n]...) } log.Debug("Invalid header encountered", "number", chunk[n].Number, "hash", chunk[n].Hash(), "err", err) return errInvalidChain } // All verifications passed, store newly found uncertain headers rollback = append(rollback, unknown...) if len(rollback) > fsHeaderSafetyNet { rollback = append(rollback[:0], rollback[len(rollback)-fsHeaderSafetyNet:]...) } } // Unless we're doing light chains, schedule the headers for associated content retrieval if d.mode == FullSync || d.mode == FastSync { // If we've reached the allowed number of pending headers, stall a bit for d.queue.PendingBlocks() >= maxQueuedHeaders || d.queue.PendingReceipts() >= maxQueuedHeaders { select { case <-d.cancelCh: return errCancelHeaderProcessing case <-time.After(time.Second): } } // Otherwise insert the headers for content retrieval inserts := d.queue.Schedule(chunk, origin) if len(inserts) != len(chunk) { log.Debug("Stale headers") return errBadPeer } } headers = headers[limit:] origin += uint64(limit) } // Update the highest block number we know if a higher one is found. d.syncStatsLock.Lock() if d.syncStatsChainHeight < origin { d.syncStatsChainHeight = origin - 1 } d.syncStatsLock.Unlock() // Signal the content downloaders of the availablility of new tasks for _, ch := range []chan bool{d.bodyWakeCh, d.receiptWakeCh} { select { case ch <- true: default: } } } } } // processFullSyncContent takes fetch results from the queue and imports them into the chain. func (d *Downloader) processFullSyncContent() error { for { results := d.queue.Results(true) if len(results) == 0 { return nil } if d.chainInsertHook != nil { d.chainInsertHook(results) } if err := d.importBlockResults(results); err != nil { return err } } } func (d *Downloader) importBlockResults(results []*fetchResult) error { // Check for any early termination requests if len(results) == 0 { return nil } select { case <-d.quitCh: return errCancelContentProcessing default: } // Retrieve the a batch of results to import first, last := results[0].Header, results[len(results)-1].Header log.Debug("Inserting downloaded chain", "items", len(results), "firstnum", first.Number, "firsthash", first.Hash(), "lastnum", last.Number, "lasthash", last.Hash(), ) blocks := make([]*types.Block, len(results)) for i, result := range results { blocks[i] = types.NewBlockWithHeader(result.Header).WithBody(result.Transactions, result.Uncles) } if index, err := d.blockchain.InsertChain(blocks); err != nil { if index < len(results) { log.Debug("Downloaded item processing failed", "number", results[index].Header.Number, "hash", results[index].Header.Hash(), "err", err) } else { // The InsertChain method in blockchain.go will sometimes return an out-of-bounds index, // when it needs to preprocess blocks to import a sidechain. // The importer will put together a new list of blocks to import, which is a superset // of the blocks delivered from the downloader, and the indexing will be off. log.Debug("Downloaded item processing failed on sidechain import", "index", index, "err", err) } return errInvalidChain } return nil } // processFastSyncContent takes fetch results from the queue and writes them to the // database. It also controls the synchronisation of state nodes of the pivot block. func (d *Downloader) processFastSyncContent(latest *types.Header) error { // Start syncing state of the reported head block. This should get us most of // the state of the pivot block. stateSync := d.syncState(latest.Root) defer stateSync.Cancel() go func() { if err := stateSync.Wait(); err != nil && err != errCancelStateFetch { d.queue.Close() // wake up Results } }() // Figure out the ideal pivot block. Note, that this goalpost may move if the // sync takes long enough for the chain head to move significantly. pivot := uint64(0) if height := latest.Number.Uint64(); height > uint64(fsMinFullBlocks) { pivot = height - uint64(fsMinFullBlocks) } // To cater for moving pivot points, track the pivot block and subsequently // accumulated download results separately. var ( oldPivot *fetchResult // Locked in pivot block, might change eventually oldTail []*fetchResult // Downloaded content after the pivot ) for { // Wait for the next batch of downloaded data to be available, and if the pivot // block became stale, move the goalpost results := d.queue.Results(oldPivot == nil) // Block if we're not monitoring pivot staleness if len(results) == 0 { // If pivot sync is done, stop if oldPivot == nil { return stateSync.Cancel() } // If sync failed, stop select { case <-d.cancelCh: return stateSync.Cancel() default: } } if d.chainInsertHook != nil { d.chainInsertHook(results) } if oldPivot != nil { results = append(append([]*fetchResult{oldPivot}, oldTail...), results...) } // Split around the pivot block and process the two sides via fast/full sync if atomic.LoadInt32(&d.committed) == 0 { latest = results[len(results)-1].Header if height := latest.Number.Uint64(); height > pivot+2*uint64(fsMinFullBlocks) { log.Warn("Pivot became stale, moving", "old", pivot, "new", height-uint64(fsMinFullBlocks)) pivot = height - uint64(fsMinFullBlocks) } } P, beforeP, afterP := splitAroundPivot(pivot, results) if err := d.commitFastSyncData(beforeP, stateSync); err != nil { return err } if P != nil { // If new pivot block found, cancel old state retrieval and restart if oldPivot != P { stateSync.Cancel() stateSync = d.syncState(P.Header.Root) defer stateSync.Cancel() go func() { if err := stateSync.Wait(); err != nil && err != errCancelStateFetch { d.queue.Close() // wake up Results } }() oldPivot = P } // Wait for completion, occasionally checking for pivot staleness select { case <-stateSync.done: if stateSync.err != nil { return stateSync.err } if err := d.commitPivotBlock(P); err != nil { return err } oldPivot = nil case <-time.After(time.Second): oldTail = afterP continue } } // Fast sync done, pivot commit done, full import if err := d.importBlockResults(afterP); err != nil { return err } } } func splitAroundPivot(pivot uint64, results []*fetchResult) (p *fetchResult, before, after []*fetchResult) { for _, result := range results { num := result.Header.Number.Uint64() switch { case num < pivot: before = append(before, result) case num == pivot: p = result default: after = append(after, result) } } return p, before, after } func (d *Downloader) commitFastSyncData(results []*fetchResult, stateSync *stateSync) error { // Check for any early termination requests if len(results) == 0 { return nil } select { case <-d.quitCh: return errCancelContentProcessing case <-stateSync.done: if err := stateSync.Wait(); err != nil { return err } default: } // Retrieve the a batch of results to import first, last := results[0].Header, results[len(results)-1].Header log.Debug("Inserting fast-sync blocks", "items", len(results), "firstnum", first.Number, "firsthash", first.Hash(), "lastnumn", last.Number, "lasthash", last.Hash(), ) blocks := make([]*types.Block, len(results)) receipts := make([]types.Receipts, len(results)) for i, result := range results { blocks[i] = types.NewBlockWithHeader(result.Header).WithBody(result.Transactions, result.Uncles) receipts[i] = result.Receipts } if index, err := d.blockchain.InsertReceiptChain(blocks, receipts, d.ancientLimit); err != nil { log.Debug("Downloaded item processing failed", "number", results[index].Header.Number, "hash", results[index].Header.Hash(), "err", err) return errInvalidChain } return nil } func (d *Downloader) commitPivotBlock(result *fetchResult) error { block := types.NewBlockWithHeader(result.Header).WithBody(result.Transactions, result.Uncles) log.Debug("Committing fast sync pivot as new head", "number", block.Number(), "hash", block.Hash()) // Commit the pivot block as the new head, will require full sync from here on if _, err := d.blockchain.InsertReceiptChain([]*types.Block{block}, []types.Receipts{result.Receipts}, d.ancientLimit); err != nil { return err } if err := d.blockchain.FastSyncCommitHead(block.Hash()); err != nil { return err } atomic.StoreInt32(&d.committed, 1) // If we had a bloom filter for the state sync, deallocate it now. Note, we only // deallocate internally, but keep the empty wrapper. This ensures that if we do // a rollback after committing the pivot and restarting fast sync, we don't end // up using a nil bloom. Empty bloom is fine, it just returns that it does not // have the info we need, so reach down to the database instead. if d.stateBloom != nil { d.stateBloom.Close() } return nil } // DeliverHeaders injects a new batch of block headers received from a remote // node into the download schedule. func (d *Downloader) DeliverHeaders(id string, headers []*types.Header) (err error) { return d.deliver(id, d.headerCh, &headerPack{id, headers}, headerInMeter, headerDropMeter) } // DeliverBodies injects a new batch of block bodies received from a remote node. func (d *Downloader) DeliverBodies(id string, transactions [][]*types.Transaction, uncles [][]*types.Header) (err error) { return d.deliver(id, d.bodyCh, &bodyPack{id, transactions, uncles}, bodyInMeter, bodyDropMeter) } // DeliverReceipts injects a new batch of receipts received from a remote node. func (d *Downloader) DeliverReceipts(id string, receipts [][]*types.Receipt) (err error) { return d.deliver(id, d.receiptCh, &receiptPack{id, receipts}, receiptInMeter, receiptDropMeter) } // DeliverNodeData injects a new batch of node state data received from a remote node. func (d *Downloader) DeliverNodeData(id string, data [][]byte) (err error) { return d.deliver(id, d.stateCh, &statePack{id, data}, stateInMeter, stateDropMeter) } // deliver injects a new batch of data received from a remote node. func (d *Downloader) deliver(id string, destCh chan dataPack, packet dataPack, inMeter, dropMeter metrics.Meter) (err error) { // Update the delivery metrics for both good and failed deliveries inMeter.Mark(int64(packet.Items())) defer func() { if err != nil { dropMeter.Mark(int64(packet.Items())) } }() // Deliver or abort if the sync is canceled while queuing d.cancelLock.RLock() cancel := d.cancelCh d.cancelLock.RUnlock() if cancel == nil { return errNoSyncActive } select { case destCh <- packet: return nil case <-cancel: return errNoSyncActive } } // qosTuner is the quality of service tuning loop that occasionally gathers the // peer latency statistics and updates the estimated request round trip time. func (d *Downloader) qosTuner() { for { // Retrieve the current median RTT and integrate into the previoust target RTT rtt := time.Duration((1-qosTuningImpact)*float64(atomic.LoadUint64(&d.rttEstimate)) + qosTuningImpact*float64(d.peers.medianRTT())) atomic.StoreUint64(&d.rttEstimate, uint64(rtt)) // A new RTT cycle passed, increase our confidence in the estimated RTT conf := atomic.LoadUint64(&d.rttConfidence) conf = conf + (1000000-conf)/2 atomic.StoreUint64(&d.rttConfidence, conf) // Log the new QoS values and sleep until the next RTT log.Debug("Recalculated downloader QoS values", "rtt", rtt, "confidence", float64(conf)/1000000.0, "ttl", d.requestTTL()) select { case <-d.quitCh: return case <-time.After(rtt): } } } // qosReduceConfidence is meant to be called when a new peer joins the downloader's // peer set, needing to reduce the confidence we have in out QoS estimates. func (d *Downloader) qosReduceConfidence() { // If we have a single peer, confidence is always 1 peers := uint64(d.peers.Len()) if peers == 0 { // Ensure peer connectivity races don't catch us off guard return } if peers == 1 { atomic.StoreUint64(&d.rttConfidence, 1000000) return } // If we have a ton of peers, don't drop confidence) if peers >= uint64(qosConfidenceCap) { return } // Otherwise drop the confidence factor conf := atomic.LoadUint64(&d.rttConfidence) * (peers - 1) / peers if float64(conf)/1000000 < rttMinConfidence { conf = uint64(rttMinConfidence * 1000000) } atomic.StoreUint64(&d.rttConfidence, conf) rtt := time.Duration(atomic.LoadUint64(&d.rttEstimate)) log.Debug("Relaxed downloader QoS values", "rtt", rtt, "confidence", float64(conf)/1000000.0, "ttl", d.requestTTL()) } // requestRTT returns the current target round trip time for a download request // to complete in. // // Note, the returned RTT is .9 of the actually estimated RTT. The reason is that // the downloader tries to adapt queries to the RTT, so multiple RTT values can // be adapted to, but smaller ones are preferred (stabler download stream). func (d *Downloader) requestRTT() time.Duration { return time.Duration(atomic.LoadUint64(&d.rttEstimate)) * 9 / 10 } // requestTTL returns the current timeout allowance for a single download request // to finish under. func (d *Downloader) requestTTL() time.Duration { var ( rtt = time.Duration(atomic.LoadUint64(&d.rttEstimate)) conf = float64(atomic.LoadUint64(&d.rttConfidence)) / 1000000.0 ) ttl := time.Duration(ttlScaling) * time.Duration(float64(rtt)/conf) if ttl > ttlLimit { ttl = ttlLimit } return ttl }