// Copyright 2021 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 import ( "encoding/json" "errors" "math/rand" "sort" "time" "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/eth/protocols/eth" "github.com/ethereum/go-ethereum/ethdb" "github.com/ethereum/go-ethereum/log" ) // scratchHeaders is the number of headers to store in a scratch space to allow // concurrent downloads. A header is about 0.5KB in size, so there is no worry // about using too much memory. The only catch is that we can only validate gaps // afer they're linked to the head, so the bigger the scratch space, the larger // potential for invalid headers. // // The current scratch space of 131072 headers is expected to use 64MB RAM. const scratchHeaders = 131072 // requestHeaders is the number of header to request from a remote peer in a single // network packet. Although the skeleton downloader takes into consideration peer // capacities when picking idlers, the packet size was decided to remain constant // since headers are relatively small and it's easier to work with fixed batches // vs. dynamic interval fillings. const requestHeaders = 512 // errSyncLinked is an internal helper error to signal that the current sync // cycle linked up to the genesis block, this the skeleton syncer should ping // the backfiller to resume. Since we already have that logic on sync start, // piggie-back on that instead of 2 entrypoints. var errSyncLinked = errors.New("sync linked") // errSyncMerged is an internal helper error to signal that the current sync // cycle merged with a previously aborted subchain, thus the skeleton syncer // should abort and restart with the new state. var errSyncMerged = errors.New("sync merged") // errSyncReorged is an internal helper error to signal that the head chain of // the current sync cycle was (partially) reorged, thus the skeleton syncer // should abort and restart with the new state. var errSyncReorged = errors.New("sync reorged") // errTerminated is returned if the sync mechanism was terminated for this run of // the process. This is usually the case when Geth is shutting down and some events // might still be propagating. var errTerminated = errors.New("terminated") // errReorgDenied is returned if an attempt is made to extend the beacon chain // with a new header, but it does not link up to the existing sync. var errReorgDenied = errors.New("non-forced head reorg denied") func init() { // Tuning parameters is nice, but the scratch space must be assignable in // full to peers. It's a useless cornercase to support a dangling half-group. if scratchHeaders%requestHeaders != 0 { panic("Please make scratchHeaders divisible by requestHeaders") } } // subchain is a contiguous header chain segment that is backed by the database, // but may not be linked to the live chain. The skeleton downloader may produce // a new one of these every time it is restarted until the subchain grows large // enough to connect with a previous subchain. // // The subchains use the exact same database namespace and are not disjoint from // each other. As such, extending one to overlap the other entails reducing the // second one first. This combined buffer model is used to avoid having to move // data on disk when two subchains are joined together. type subchain struct { Head uint64 // Block number of the newest header in the subchain Tail uint64 // Block number of the oldest header in the subchain Next common.Hash // Block hash of the next oldest header in the subchain } // skeletonProgress is a database entry to allow suspending and resuming a chain // sync. As the skeleton header chain is downloaded backwards, restarts can and // will produce temporarily disjoint subchains. There is no way to restart a // suspended skeleton sync without prior knowledge of all prior suspension points. type skeletonProgress struct { Subchains []*subchain // Disjoint subchains downloaded until now } // headUpdate is a notification that the beacon sync should switch to a new target. // The update might request whether to forcefully change the target, or only try to // extend it and fail if it's not possible. type headUpdate struct { header *types.Header // Header to update the sync target to force bool // Whether to force the update or only extend if possible errc chan error // Channel to signal acceptance of the new head } // headerRequest tracks a pending header request to ensure responses are to // actual requests and to validate any security constraints. // // Concurrency note: header requests and responses are handled concurrently from // the main runloop to allow Keccak256 hash verifications on the peer's thread and // to drop on invalid response. The request struct must contain all the data to // construct the response without accessing runloop internals (i.e. subchains). // That is only included to allow the runloop to match a response to the task being // synced without having yet another set of maps. type headerRequest struct { peer string // Peer to which this request is assigned id uint64 // Request ID of this request deliver chan *headerResponse // Channel to deliver successful response on revert chan *headerRequest // Channel to deliver request failure on cancel chan struct{} // Channel to track sync cancellation stale chan struct{} // Channel to signal the request was dropped head uint64 // Head number of the requested batch of headers } // headerResponse is an already verified remote response to a header request. type headerResponse struct { peer *peerConnection // Peer from which this response originates reqid uint64 // Request ID that this response fulfils headers []*types.Header // Chain of headers } // backfiller is a callback interface through which the skeleton sync can tell // the downloader that it should suspend or resume backfilling on specific head // events (e.g. suspend on forks or gaps, resume on successful linkups). type backfiller interface { // suspend requests the backfiller to abort any running full or snap sync // based on the skeleton chain as it might be invalid. The backfiller should // gracefully handle multiple consecutive suspends without a resume, even // on initial sartup. suspend() // resume requests the backfiller to start running fill or snap sync based on // the skeleton chain as it has successfully been linked. Appending new heads // to the end of the chain will not result in suspend/resume cycles. resume() } // skeleton represents a header chain synchronized after the merge where blocks // aren't validated any more via PoW in a forward fashion, rather are dictated // and extended at the head via the beacon chain and backfilled on the original // Ethereum block sync protocol. // // Since the skeleton is grown backwards from head to genesis, it is handled as // a separate entity, not mixed in with the logical sequential transition of the // blocks. Once the skeleton is connected to an existing, validated chain, the // headers will be moved into the main downloader for filling and execution. // // Opposed to the original Ethereum block synchronization which is trustless (and // uses a master peer to minimize the attack surface), post-merge block sync starts // from a trusted head. As such, there is no need for a master peer any more and // headers can be requested fully concurrently (though some batches might be // discarded if they don't link up correctly). // // Although a skeleton is part of a sync cycle, it is not recreated, rather stays // alive throughout the lifetime of the downloader. This allows it to be extended // concurrently with the sync cycle, since extensions arrive from an API surface, // not from within (vs. legacy Ethereum sync). // // Since the skeleton tracks the entire header chain until it is consumed by the // forward block filling, it needs 0.5KB/block storage. At current mainnet sizes // this is only possible with a disk backend. Since the skeleton is separate from // the node's header chain, storing the headers ephemerally until sync finishes // is wasted disk IO, but it's a price we're going to pay to keep things simple // for now. type skeleton struct { db ethdb.Database // Database backing the skeleton filler backfiller // Chain syncer suspended/resumed by head events peers *peerSet // Set of peers we can sync from idles map[string]*peerConnection // Set of idle peers in the current sync cycle drop peerDropFn // Drops a peer for misbehaving progress *skeletonProgress // Sync progress tracker for resumption and metrics started time.Time // Timestamp when the skeleton syncer was created logged time.Time // Timestamp when progress was last logged to the user pulled uint64 // Number of headers downloaded in this run scratchSpace []*types.Header // Scratch space to accumulate headers in (first = recent) scratchOwners []string // Peer IDs owning chunks of the scratch space (pend or delivered) scratchHead uint64 // Block number of the first item in the scratch space requests map[uint64]*headerRequest // Header requests currently running headEvents chan *headUpdate // Notification channel for new heads terminate chan chan error // Termination channel to abort sync terminated chan struct{} // Channel to signal that the syner is dead // Callback hooks used during testing syncStarting func() // callback triggered after a sync cycle is inited but before started } // newSkeleton creates a new sync skeleton that tracks a potentially dangling // header chain until it's linked into an existing set of blocks. func newSkeleton(db ethdb.Database, peers *peerSet, drop peerDropFn, filler backfiller) *skeleton { sk := &skeleton{ db: db, filler: filler, peers: peers, drop: drop, requests: make(map[uint64]*headerRequest), headEvents: make(chan *headUpdate), terminate: make(chan chan error), terminated: make(chan struct{}), } go sk.startup() return sk } // startup is an initial background loop which waits for an event to start or // tear the syncer down. This is required to make the skeleton sync loop once // per process but at the same time not start before the beacon chain announces // a new (existing) head. func (s *skeleton) startup() { // Close a notification channel so anyone sending us events will know if the // sync loop was torn down for good. defer close(s.terminated) // Wait for startup or teardown. This wait might loop a few times if a beacon // client requests sync head extensions, but not forced reorgs (i.e. they are // giving us new payloads without setting a starting head initially). for { select { case errc := <-s.terminate: // No head was announced but Geth is shutting down errc <- nil return case event := <-s.headEvents: // New head announced, start syncing to it, looping every time a current // cycle is terminated due to a chain event (head reorg, old chain merge). if !event.force { event.errc <- errors.New("forced head needed for startup") continue } event.errc <- nil // forced head accepted for startup head := event.header s.started = time.Now() for { // If the sync cycle terminated or was terminated, propagate up when // higher layers request termination. There's no fancy explicit error // signalling as the sync loop should never terminate (TM). newhead, err := s.sync(head) switch { case err == errSyncLinked: // Sync cycle linked up to the genesis block. Tear down the loop // and restart it so, it can properly notify the backfiller. Don't // account a new head. head = nil case err == errSyncMerged: // Subchains were merged, we just need to reinit the internal // start to continue on the tail of the merged chain. Don't // announce a new head, head = nil case err == errSyncReorged: // The subchain being synced got modified at the head in a // way that requires resyncing it. Restart sync with the new // head to force a cleanup. head = newhead case err == errTerminated: // Sync was requested to be terminated from within, stop and // return (no need to pass a message, was already done internally) return default: // Sync either successfully terminated or failed with an unhandled // error. Abort and wait until Geth requests a termination. errc := <-s.terminate errc <- err return } } } } } // Terminate tears down the syncer indefinitely. func (s *skeleton) Terminate() error { // Request termination and fetch any errors errc := make(chan error) s.terminate <- errc err := <-errc // Wait for full shutdown (not necessary, but cleaner) <-s.terminated return err } // Sync starts or resumes a previous sync cycle to download and maintain a reverse // header chain starting at the head and leading towards genesis to an available // ancestor. // // This method does not block, rather it just waits until the syncer receives the // fed header. What the syncer does with it is the syncer's problem. func (s *skeleton) Sync(head *types.Header, force bool) error { log.Trace("New skeleton head announced", "number", head.Number, "hash", head.Hash(), "force", force) errc := make(chan error) select { case s.headEvents <- &headUpdate{header: head, force: force, errc: errc}: return <-errc case <-s.terminated: return errTerminated } } // sync is the internal version of Sync that executes a single sync cycle, either // until some termination condition is reached, or until the current cycle merges // with a previously aborted run. func (s *skeleton) sync(head *types.Header) (*types.Header, error) { // If we're continuing a previous merge interrupt, just access the existing // old state without initing from disk. if head == nil { head = rawdb.ReadSkeletonHeader(s.db, s.progress.Subchains[0].Head) } else { // Otherwise, initialize the sync, trimming and previous leftovers until // we're consistent with the newly requested chain head s.initSync(head) } // Create the scratch space to fill with concurrently downloaded headers s.scratchSpace = make([]*types.Header, scratchHeaders) defer func() { s.scratchSpace = nil }() // don't hold on to references after sync s.scratchOwners = make([]string, scratchHeaders/requestHeaders) defer func() { s.scratchOwners = nil }() // don't hold on to references after sync s.scratchHead = s.progress.Subchains[0].Tail - 1 // tail must not be 0! // If the sync is already done, resume the backfiller. When the loop stops, // terminate the backfiller too. linked := len(s.progress.Subchains) == 1 && rawdb.HasBody(s.db, s.progress.Subchains[0].Next, s.scratchHead) && rawdb.HasReceipts(s.db, s.progress.Subchains[0].Next, s.scratchHead) if linked { s.filler.resume() } defer s.filler.suspend() // Create a set of unique channels for this sync cycle. We need these to be // ephemeral so a data race doesn't accidentally deliver something stale on // a persistent channel across syncs (yup, this happened) var ( requestFails = make(chan *headerRequest) responses = make(chan *headerResponse) ) cancel := make(chan struct{}) defer close(cancel) log.Debug("Starting reverse header sync cycle", "head", head.Number, "hash", head.Hash(), "cont", s.scratchHead) // Whether sync completed or not, disregard any future packets defer func() { log.Debug("Terminating reverse header sync cycle", "head", head.Number, "hash", head.Hash(), "cont", s.scratchHead) s.requests = make(map[uint64]*headerRequest) }() // Start tracking idle peers for task assignments peering := make(chan *peeringEvent, 64) // arbitrary buffer, just some burst protection peeringSub := s.peers.SubscribeEvents(peering) defer peeringSub.Unsubscribe() s.idles = make(map[string]*peerConnection) for _, peer := range s.peers.AllPeers() { s.idles[peer.id] = peer } // Nofity any tester listening for startup events if s.syncStarting != nil { s.syncStarting() } for { // Something happened, try to assign new tasks to any idle peers if !linked { s.assignTasks(responses, requestFails, cancel) } // Wait for something to happen select { case event := <-peering: // A peer joined or left, the tasks queue and allocations need to be // checked for potential assignment or reassignment peerid := event.peer.id if event.join { log.Debug("Joining skeleton peer", "id", peerid) s.idles[peerid] = event.peer } else { log.Debug("Leaving skeleton peer", "id", peerid) s.revertRequests(peerid) delete(s.idles, peerid) } case errc := <-s.terminate: errc <- nil return nil, errTerminated case event := <-s.headEvents: // New head was announced, try to integrate it. If successful, nothing // needs to be done as the head simply extended the last range. For now // we don't seamlessly integrate reorgs to keep things simple. If the // network starts doing many mini reorgs, it might be worthwhile handling // a limited depth without an error. if reorged := s.processNewHead(event.header, event.force); reorged { // If a reorg is needed, and we're forcing the new head, signal // the syncer to tear down and start over. Otherwise, drop the // non-force reorg. if event.force { event.errc <- nil // forced head reorg accepted return event.header, errSyncReorged } event.errc <- errReorgDenied continue } event.errc <- nil // head extension accepted // New head was integrated into the skeleton chain. If the backfiller // is still running, it will pick it up. If it already terminated, // a new cycle needs to be spun up. if linked { s.filler.resume() } case req := <-requestFails: s.revertRequest(req) case res := <-responses: // Process the batch of headers. If though processing we managed to // link the current subchain to a previously downloaded one, abort the // sync and restart with the merged subchains. // // If we managed to link to the existing local chain or genesis block, // abort sync altogether. linked, merged := s.processResponse(res) if linked { log.Debug("Beacon sync linked to local chain") return nil, errSyncLinked } if merged { log.Debug("Beacon sync merged subchains") return nil, errSyncMerged } // We still have work to do, loop and repeat } } } // initSync attempts to get the skeleton sync into a consistent state wrt any // past state on disk and the newly requested head to sync to. If the new head // is nil, the method will return and continue from the previous head. func (s *skeleton) initSync(head *types.Header) { // Extract the head number, we'll need it all over number := head.Number.Uint64() // Retrieve the previously saved sync progress if status := rawdb.ReadSkeletonSyncStatus(s.db); len(status) > 0 { s.progress = new(skeletonProgress) if err := json.Unmarshal(status, s.progress); err != nil { log.Error("Failed to decode skeleton sync status", "err", err) } else { // Previous sync was available, print some continuation logs for _, subchain := range s.progress.Subchains { log.Debug("Restarting skeleton subchain", "head", subchain.Head, "tail", subchain.Tail) } // Create a new subchain for the head (unless the last can be extended), // trimming anything it would overwrite headchain := &subchain{ Head: number, Tail: number, Next: head.ParentHash, } for len(s.progress.Subchains) > 0 { // If the last chain is above the new head, delete altogether lastchain := s.progress.Subchains[0] if lastchain.Tail >= headchain.Tail { log.Debug("Dropping skeleton subchain", "head", lastchain.Head, "tail", lastchain.Tail) s.progress.Subchains = s.progress.Subchains[1:] continue } // Otherwise truncate the last chain if needed and abort trimming if lastchain.Head >= headchain.Tail { log.Debug("Trimming skeleton subchain", "oldhead", lastchain.Head, "newhead", headchain.Tail-1, "tail", lastchain.Tail) lastchain.Head = headchain.Tail - 1 } break } // If the last subchain can be extended, we're lucky. Otherwise create // a new subchain sync task. var extended bool if n := len(s.progress.Subchains); n > 0 { lastchain := s.progress.Subchains[0] if lastchain.Head == headchain.Tail-1 { lasthead := rawdb.ReadSkeletonHeader(s.db, lastchain.Head) if lasthead.Hash() == head.ParentHash { log.Debug("Extended skeleton subchain with new head", "head", headchain.Tail, "tail", lastchain.Tail) lastchain.Head = headchain.Tail extended = true } } } if !extended { log.Debug("Created new skeleton subchain", "head", number, "tail", number) s.progress.Subchains = append([]*subchain{headchain}, s.progress.Subchains...) } // Update the database with the new sync stats and insert the new // head header. We won't delete any trimmed skeleton headers since // those will be outside the index space of the many subchains and // the database space will be reclaimed eventually when processing // blocks above the current head (TODO(karalabe): don't forget). batch := s.db.NewBatch() rawdb.WriteSkeletonHeader(batch, head) s.saveSyncStatus(batch) if err := batch.Write(); err != nil { log.Crit("Failed to write skeleton sync status", "err", err) } return } } // Either we've failed to decode the previus state, or there was none. Start // a fresh sync with a single subchain represented by the currently sent // chain head. s.progress = &skeletonProgress{ Subchains: []*subchain{ { Head: number, Tail: number, Next: head.ParentHash, }, }, } batch := s.db.NewBatch() rawdb.WriteSkeletonHeader(batch, head) s.saveSyncStatus(batch) if err := batch.Write(); err != nil { log.Crit("Failed to write initial skeleton sync status", "err", err) } log.Debug("Created initial skeleton subchain", "head", number, "tail", number) } // saveSyncStatus marshals the remaining sync tasks into leveldb. func (s *skeleton) saveSyncStatus(db ethdb.KeyValueWriter) { status, err := json.Marshal(s.progress) if err != nil { panic(err) // This can only fail during implementation } rawdb.WriteSkeletonSyncStatus(db, status) } // processNewHead does the internal shuffling for a new head marker and either // accepts and integrates it into the skeleton or requests a reorg. Upon reorg, // the syncer will tear itself down and restart with a fresh head. It is simpler // to reconstruct the sync state than to mutate it and hope for the best. func (s *skeleton) processNewHead(head *types.Header, force bool) bool { // If the header cannot be inserted without interruption, return an error for // the outer loop to tear down the skeleton sync and restart it number := head.Number.Uint64() lastchain := s.progress.Subchains[0] if lastchain.Tail >= number { if force { log.Warn("Beacon chain reorged", "tail", lastchain.Tail, "newHead", number) } return true } if lastchain.Head+1 < number { if force { log.Warn("Beacon chain gapped", "head", lastchain.Head, "newHead", number) } return true } if parent := rawdb.ReadSkeletonHeader(s.db, number-1); parent.Hash() != head.ParentHash { if force { log.Warn("Beacon chain forked", "ancestor", parent.Number, "hash", parent.Hash(), "want", head.ParentHash) } return true } // New header seems to be in the last subchain range. Unwind any extra headers // from the chain tip and insert the new head. We won't delete any trimmed // skeleton headers since those will be outside the index space of the many // subchains and the database space will be reclaimed eventually when processing // blocks above the current head (TODO(karalabe): don't forget). batch := s.db.NewBatch() rawdb.WriteSkeletonHeader(batch, head) lastchain.Head = number s.saveSyncStatus(batch) if err := batch.Write(); err != nil { log.Crit("Failed to write skeleton sync status", "err", err) } return false } // assignTasks attempts to match idle peers to pending header retrievals. func (s *skeleton) assignTasks(success chan *headerResponse, fail chan *headerRequest, cancel chan struct{}) { // Sort the peers by download capacity to use faster ones if many available idlers := &peerCapacitySort{ peers: make([]*peerConnection, 0, len(s.idles)), caps: make([]int, 0, len(s.idles)), } targetTTL := s.peers.rates.TargetTimeout() for _, peer := range s.idles { idlers.peers = append(idlers.peers, peer) idlers.caps = append(idlers.caps, s.peers.rates.Capacity(peer.id, eth.BlockHeadersMsg, targetTTL)) } if len(idlers.peers) == 0 { return } sort.Sort(idlers) // Find header regions not yet downloading and fill them for task, owner := range s.scratchOwners { // If we're out of idle peers, stop assigning tasks if len(idlers.peers) == 0 { return } // Skip any tasks already filling if owner != "" { continue } // If we've reached the genesis, stop assigning tasks if uint64(task*requestHeaders) >= s.scratchHead { return } // Found a task and have peers available, assign it idle := idlers.peers[0] idlers.peers = idlers.peers[1:] idlers.caps = idlers.caps[1:] // Matched a pending task to an idle peer, allocate a unique request id var reqid uint64 for { reqid = uint64(rand.Int63()) if reqid == 0 { continue } if _, ok := s.requests[reqid]; ok { continue } break } // Generate the network query and send it to the peer req := &headerRequest{ peer: idle.id, id: reqid, deliver: success, revert: fail, cancel: cancel, stale: make(chan struct{}), head: s.scratchHead - uint64(task*requestHeaders), } s.requests[reqid] = req delete(s.idles, idle.id) // Generate the network query and send it to the peer go s.executeTask(idle, req) // Inject the request into the task to block further assignments s.scratchOwners[task] = idle.id } } // executeTask executes a single fetch request, blocking until either a result // arrives or a timeouts / cancellation is triggered. The method should be run // on its own goroutine and will deliver on the requested channels. func (s *skeleton) executeTask(peer *peerConnection, req *headerRequest) { start := time.Now() resCh := make(chan *eth.Response) // Figure out how many headers to fetch. Usually this will be a full batch, // but for the very tail of the chain, trim the request to the number left. // Since nodes may or may not return the genesis header for a batch request, // don't even request it. The parent hash of block #1 is enough to link. requestCount := requestHeaders if req.head < requestHeaders { requestCount = int(req.head) } peer.log.Trace("Fetching skeleton headers", "from", req.head, "count", requestCount) netreq, err := peer.peer.RequestHeadersByNumber(req.head, requestCount, 0, true, resCh) if err != nil { peer.log.Trace("Failed to request headers", "err", err) s.scheduleRevertRequest(req) return } defer netreq.Close() // Wait until the response arrives, the request is cancelled or times out ttl := s.peers.rates.TargetTimeout() timeoutTimer := time.NewTimer(ttl) defer timeoutTimer.Stop() select { case <-req.cancel: peer.log.Debug("Header request cancelled") s.scheduleRevertRequest(req) case <-timeoutTimer.C: // Header retrieval timed out, update the metrics peer.log.Warn("Header request timed out, dropping peer", "elapsed", ttl) headerTimeoutMeter.Mark(1) s.peers.rates.Update(peer.id, eth.BlockHeadersMsg, 0, 0) s.scheduleRevertRequest(req) // At this point we either need to drop the offending peer, or we need a // mechanism to allow waiting for the response and not cancel it. For now // lets go with dropping since the header sizes are deterministic and the // beacon sync runs exclusive (downloader is idle) so there should be no // other load to make timeouts probable. If we notice that timeouts happen // more often than we'd like, we can introduce a tracker for the requests // gone stale and monitor them. However, in that case too, we need a way // to protect against malicious peers never responding, so it would need // a second, hard-timeout mechanism. s.drop(peer.id) case res := <-resCh: // Headers successfully retrieved, update the metrics headers := *res.Res.(*eth.BlockHeadersPacket) headerReqTimer.Update(time.Since(start)) s.peers.rates.Update(peer.id, eth.BlockHeadersMsg, res.Time, len(headers)) // Cross validate the headers with the requests switch { case len(headers) == 0: // No headers were delivered, reject the response and reschedule peer.log.Debug("No headers delivered") res.Done <- errors.New("no headers delivered") s.scheduleRevertRequest(req) case headers[0].Number.Uint64() != req.head: // Header batch anchored at non-requested number peer.log.Debug("Invalid header response head", "have", headers[0].Number, "want", req.head) res.Done <- errors.New("invalid header batch anchor") s.scheduleRevertRequest(req) case req.head >= requestHeaders && len(headers) != requestHeaders: // Invalid number of non-genesis headers delivered, reject the response and reschedule peer.log.Debug("Invalid non-genesis header count", "have", len(headers), "want", requestHeaders) res.Done <- errors.New("not enough non-genesis headers delivered") s.scheduleRevertRequest(req) case req.head < requestHeaders && uint64(len(headers)) != req.head: // Invalid number of genesis headers delivered, reject the response and reschedule peer.log.Debug("Invalid genesis header count", "have", len(headers), "want", headers[0].Number.Uint64()) res.Done <- errors.New("not enough genesis headers delivered") s.scheduleRevertRequest(req) default: // Packet seems structurally valid, check hash progression and if it // is correct too, deliver for storage for i := 0; i < len(headers)-1; i++ { if headers[i].ParentHash != headers[i+1].Hash() { peer.log.Debug("Invalid hash progression", "index", i, "wantparenthash", headers[i].ParentHash, "haveparenthash", headers[i+1].Hash()) res.Done <- errors.New("invalid hash progression") s.scheduleRevertRequest(req) return } } // Hash chain is valid. The delivery might still be junk as we're // downloading batches concurrently (so no way to link the headers // until gaps are filled); in that case, we'll nuke the peer when // we detect the fault. res.Done <- nil select { case req.deliver <- &headerResponse{ peer: peer, reqid: req.id, headers: headers, }: case <-req.cancel: } } } } // revertRequests locates all the currently pending reuqests from a particular // peer and reverts them, rescheduling for others to fulfill. func (s *skeleton) revertRequests(peer string) { // Gather the requests first, revertals need the lock too var requests []*headerRequest for _, req := range s.requests { if req.peer == peer { requests = append(requests, req) } } // Revert all the requests matching the peer for _, req := range requests { s.revertRequest(req) } } // scheduleRevertRequest asks the event loop to clean up a request and return // all failed retrieval tasks to the scheduler for reassignment. func (s *skeleton) scheduleRevertRequest(req *headerRequest) { select { case req.revert <- req: // Sync event loop notified case <-req.cancel: // Sync cycle got cancelled case <-req.stale: // Request already reverted } } // revertRequest cleans up a request and returns all failed retrieval tasks to // the scheduler for reassignment. // // Note, this needs to run on the event runloop thread to reschedule to idle peers. // On peer threads, use scheduleRevertRequest. func (s *skeleton) revertRequest(req *headerRequest) { log.Trace("Reverting header request", "peer", req.peer, "reqid", req.id) select { case <-req.stale: log.Trace("Header request already reverted", "peer", req.peer, "reqid", req.id) return default: } close(req.stale) // Remove the request from the tracked set delete(s.requests, req.id) // Remove the request from the tracked set and mark the task as not-pending, // ready for resheduling s.scratchOwners[(s.scratchHead-req.head)/requestHeaders] = "" } func (s *skeleton) processResponse(res *headerResponse) (linked bool, merged bool) { res.peer.log.Trace("Processing header response", "head", res.headers[0].Number, "hash", res.headers[0].Hash(), "count", len(res.headers)) // Whether the response is valid, we can mark the peer as idle and notify // the scheduler to assign a new task. If the response is invalid, we'll // drop the peer in a bit. s.idles[res.peer.id] = res.peer // Ensure the response is for a valid request if _, ok := s.requests[res.reqid]; !ok { // Some internal accounting is broken. A request either times out or it // gets fulfilled successfully. It should not be possible to deliver a // response to a non-existing request. res.peer.log.Error("Unexpected header packet") return false, false } delete(s.requests, res.reqid) // Insert the delivered headers into the scratch space independent of the // content or continuation; those will be validated in a moment head := res.headers[0].Number.Uint64() copy(s.scratchSpace[s.scratchHead-head:], res.headers) // If there's still a gap in the head of the scratch space, abort if s.scratchSpace[0] == nil { return false, false } // Try to consume any head headers, validating the boundary conditions batch := s.db.NewBatch() for s.scratchSpace[0] != nil { // Next batch of headers available, cross-reference with the subchain // we are extending and either accept or discard if s.progress.Subchains[0].Next != s.scratchSpace[0].Hash() { // Print a log messages to track what's going on tail := s.progress.Subchains[0].Tail want := s.progress.Subchains[0].Next have := s.scratchSpace[0].Hash() log.Warn("Invalid skeleton headers", "peer", s.scratchOwners[0], "number", tail-1, "want", want, "have", have) // The peer delivered junk, or at least not the subchain we are // syncing to. Free up the scratch space and assignment, reassign // and drop the original peer. for i := 0; i < requestHeaders; i++ { s.scratchSpace[i] = nil } s.drop(s.scratchOwners[0]) s.scratchOwners[0] = "" break } // Scratch delivery matches required subchain, deliver the batch of // headers and push the subchain forward var consumed int for _, header := range s.scratchSpace[:requestHeaders] { if header != nil { // nil when the genesis is reached consumed++ rawdb.WriteSkeletonHeader(batch, header) s.pulled++ s.progress.Subchains[0].Tail-- s.progress.Subchains[0].Next = header.ParentHash // If we've reached an existing block in the chain, stop retrieving // headers. Note, if we want to support light clients with the same // code we'd need to switch here based on the downloader mode. That // said, there's no such functionality for now, so don't complicate. // // In the case of full sync it would be enough to check for the body, // but even a full syncing node will generate a receipt once block // processing is done, so it's just one more "needless" check. var ( hasBody = rawdb.HasBody(s.db, header.ParentHash, header.Number.Uint64()-1) hasReceipt = rawdb.HasReceipts(s.db, header.ParentHash, header.Number.Uint64()-1) ) if hasBody && hasReceipt { linked = true break } } } head := s.progress.Subchains[0].Head tail := s.progress.Subchains[0].Tail next := s.progress.Subchains[0].Next log.Trace("Primary subchain extended", "head", head, "tail", tail, "next", next) // If the beacon chain was linked to the local chain, completely swap out // all internal progress and abort header synchronization. if linked { // Note, linking into the local chain should also mean that there are // no leftover subchains, but just in case there's some junk due to // strange conditions or bugs, clean up all internal state. if len(s.progress.Subchains) > 1 { log.Error("Cleaning up leftovers after beacon link") s.progress.Subchains = s.progress.Subchains[:1] } break } // Batch of headers consumed, shift the download window forward copy(s.scratchSpace, s.scratchSpace[requestHeaders:]) for i := 0; i < requestHeaders; i++ { s.scratchSpace[scratchHeaders-i-1] = nil } copy(s.scratchOwners, s.scratchOwners[1:]) s.scratchOwners[scratchHeaders/requestHeaders-1] = "" s.scratchHead -= uint64(consumed) // If the subchain extended into the next subchain, we need to handle // the overlap. Since there could be many overlaps (come on), do this // in a loop. for len(s.progress.Subchains) > 1 && s.progress.Subchains[1].Head >= s.progress.Subchains[0].Tail { // Extract some stats from the second subchain head := s.progress.Subchains[1].Head tail := s.progress.Subchains[1].Tail next := s.progress.Subchains[1].Next // Since we just overwrote part of the next subchain, we need to trim // its head independent of matching or mismatching content if s.progress.Subchains[1].Tail >= s.progress.Subchains[0].Tail { // Fully overwritten, get rid of the subchain as a whole log.Debug("Previous subchain fully overwritten", "head", head, "tail", tail, "next", next) s.progress.Subchains = append(s.progress.Subchains[:1], s.progress.Subchains[2:]...) continue } else { // Partially overwritten, trim the head to the overwritten size log.Debug("Previous subchain partially overwritten", "head", head, "tail", tail, "next", next) s.progress.Subchains[1].Head = s.progress.Subchains[0].Tail - 1 } // If the old subchain is an extension of the new one, merge the two // and let the skeleton syncer restart (to clean internal state) if rawdb.ReadSkeletonHeader(s.db, s.progress.Subchains[1].Head).Hash() == s.progress.Subchains[0].Next { log.Debug("Previous subchain merged", "head", head, "tail", tail, "next", next) s.progress.Subchains[0].Tail = s.progress.Subchains[1].Tail s.progress.Subchains[0].Next = s.progress.Subchains[1].Next s.progress.Subchains = append(s.progress.Subchains[:1], s.progress.Subchains[2:]...) merged = true } } // If subchains were merged, all further available headers in the scratch // space are invalid since we skipped ahead. Stop processing the scratch // space to avoid dropping peers thinking they delivered invalid data. if merged { break } } s.saveSyncStatus(batch) if err := batch.Write(); err != nil { log.Crit("Failed to write skeleton headers and progress", "err", err) } // Print a progress report making the UX a bit nicer left := s.progress.Subchains[0].Tail - 1 if linked { left = 0 } if time.Since(s.logged) > 8*time.Second || left == 0 { s.logged = time.Now() if s.pulled == 0 { log.Info("Beacon sync starting", "left", left) } else { eta := float64(time.Since(s.started)) / float64(s.pulled) * float64(left) log.Info("Syncing beacon headers", "downloaded", s.pulled, "left", left, "eta", common.PrettyDuration(eta)) } } return linked, merged } // Bounds retrieves the current head and tail tracked by the skeleton syncer. // This method is used by the backfiller, whose life cycle is controlled by the // skeleton syncer. // // Note, the method will not use the internal state of the skeleton, but will // rather blindly pull stuff from the database. This is fine, because the back- // filler will only run when the skeleton chain is fully downloaded and stable. // There might be new heads appended, but those are atomic from the perspective // of this method. Any head reorg will first tear down the backfiller and only // then make the modification. func (s *skeleton) Bounds() (head *types.Header, tail *types.Header, err error) { // Read the current sync progress from disk and figure out the current head. // Although there's a lot of error handling here, these are mostly as sanity // checks to avoid crashing if a programming error happens. These should not // happen in live code. status := rawdb.ReadSkeletonSyncStatus(s.db) if len(status) == 0 { return nil, nil, errors.New("beacon sync not yet started") } progress := new(skeletonProgress) if err := json.Unmarshal(status, progress); err != nil { return nil, nil, err } head = rawdb.ReadSkeletonHeader(s.db, progress.Subchains[0].Head) tail = rawdb.ReadSkeletonHeader(s.db, progress.Subchains[0].Tail) return head, tail, nil } // Header retrieves a specific header tracked by the skeleton syncer. This method // is meant to be used by the backfiller, whose life cycle is controlled by the // skeleton syncer. // // Note, outside the permitted runtimes, this method might return nil results and // subsequent calls might return headers from different chains. func (s *skeleton) Header(number uint64) *types.Header { return rawdb.ReadSkeletonHeader(s.db, number) }