package initialsync import ( "context" "fmt" "sync" "time" "github.com/kevinms/leakybucket-go" "github.com/libp2p/go-libp2p-core/peer" "github.com/pkg/errors" types "github.com/prysmaticlabs/eth2-types" "github.com/prysmaticlabs/prysm/beacon-chain/db" "github.com/prysmaticlabs/prysm/beacon-chain/p2p" p2pTypes "github.com/prysmaticlabs/prysm/beacon-chain/p2p/types" prysmsync "github.com/prysmaticlabs/prysm/beacon-chain/sync" "github.com/prysmaticlabs/prysm/cmd/beacon-chain/flags" "github.com/prysmaticlabs/prysm/config/params" "github.com/prysmaticlabs/prysm/crypto/rand" p2ppb "github.com/prysmaticlabs/prysm/proto/prysm/v1alpha1" "github.com/prysmaticlabs/prysm/proto/prysm/v1alpha1/block" "github.com/sirupsen/logrus" "go.opencensus.io/trace" ) const ( // maxPendingRequests limits how many concurrent fetch request one can initiate. maxPendingRequests = 64 // peersPercentagePerRequest caps percentage of peers to be used in a request. peersPercentagePerRequest = 0.75 // handshakePollingInterval is a polling interval for checking the number of received handshakes. handshakePollingInterval = 5 * time.Second // peerLocksPollingInterval is a polling interval for checking if there are stale peer locks. peerLocksPollingInterval = 5 * time.Minute // peerLockMaxAge is maximum time before stale lock is purged. peerLockMaxAge = 60 * time.Minute // nonSkippedSlotsFullSearchEpochs how many epochs to check in full, before resorting to random // sampling of slots once per epoch nonSkippedSlotsFullSearchEpochs = 10 // peerFilterCapacityWeight defines how peer's capacity affects peer's score. Provided as // percentage, i.e. 0.3 means capacity will determine 30% of peer's score. peerFilterCapacityWeight = 0.2 // backtrackingMaxHops how many hops (during search for common ancestor in backtracking) to do // before giving up. backtrackingMaxHops = 128 ) var ( errNoPeersAvailable = errors.New("no peers available, waiting for reconnect") errFetcherCtxIsDone = errors.New("fetcher's context is done, reinitialize") errSlotIsTooHigh = errors.New("slot is higher than the finalized slot") errBlockAlreadyProcessed = errors.New("block is already processed") errParentDoesNotExist = errors.New("beacon node doesn't have a parent in db with root") errNoPeersWithAltBlocks = errors.New("no peers with alternative blocks found") ) // blocksFetcherConfig is a config to setup the block fetcher. type blocksFetcherConfig struct { chain blockchainService p2p p2p.P2P db db.ReadOnlyDatabase peerFilterCapacityWeight float64 mode syncMode } // blocksFetcher is a service to fetch chain data from peers. // On an incoming requests, requested block range is evenly divided // among available peers (for fair network load distribution). type blocksFetcher struct { sync.Mutex ctx context.Context cancel context.CancelFunc rand *rand.Rand chain blockchainService p2p p2p.P2P db db.ReadOnlyDatabase blocksPerSecond uint64 rateLimiter *leakybucket.Collector peerLocks map[peer.ID]*peerLock fetchRequests chan *fetchRequestParams fetchResponses chan *fetchRequestResponse capacityWeight float64 // how remaining capacity affects peer selection mode syncMode // allows to use fetcher in different sync scenarios quit chan struct{} // termination notifier } // peerLock restricts fetcher actions on per peer basis. Currently, used for rate limiting. type peerLock struct { sync.Mutex accessed time.Time } // fetchRequestParams holds parameters necessary to schedule a fetch request. type fetchRequestParams struct { ctx context.Context // if provided, it is used instead of global fetcher's context start types.Slot // starting slot count uint64 // how many slots to receive (fetcher may return fewer slots) } // fetchRequestResponse is a combined type to hold results of both successful executions and errors. // Valid usage pattern will be to check whether result's `err` is nil, before using `blocks`. type fetchRequestResponse struct { pid peer.ID start types.Slot count uint64 blocks []block.SignedBeaconBlock err error } // newBlocksFetcher creates ready to use fetcher. func newBlocksFetcher(ctx context.Context, cfg *blocksFetcherConfig) *blocksFetcher { blocksPerSecond := flags.Get().BlockBatchLimit allowedBlocksBurst := flags.Get().BlockBatchLimitBurstFactor * flags.Get().BlockBatchLimit // Allow fetcher to go almost to the full burst capacity (less a single batch). rateLimiter := leakybucket.NewCollector( float64(blocksPerSecond), int64(allowedBlocksBurst-blocksPerSecond), false /* deleteEmptyBuckets */) capacityWeight := cfg.peerFilterCapacityWeight if capacityWeight >= 1 { capacityWeight = peerFilterCapacityWeight } ctx, cancel := context.WithCancel(ctx) return &blocksFetcher{ ctx: ctx, cancel: cancel, rand: rand.NewGenerator(), chain: cfg.chain, p2p: cfg.p2p, db: cfg.db, blocksPerSecond: uint64(blocksPerSecond), rateLimiter: rateLimiter, peerLocks: make(map[peer.ID]*peerLock), fetchRequests: make(chan *fetchRequestParams, maxPendingRequests), fetchResponses: make(chan *fetchRequestResponse, maxPendingRequests), capacityWeight: capacityWeight, mode: cfg.mode, quit: make(chan struct{}), } } // start boots up the fetcher, which starts listening for incoming fetch requests. func (f *blocksFetcher) start() error { select { case <-f.ctx.Done(): return errFetcherCtxIsDone default: go f.loop() return nil } } // stop terminates all fetcher operations. func (f *blocksFetcher) stop() { defer func() { if f.rateLimiter != nil { f.rateLimiter.Free() f.rateLimiter = nil } }() f.cancel() <-f.quit // make sure that loop() is done } // requestResponses exposes a channel into which fetcher pushes generated request responses. func (f *blocksFetcher) requestResponses() <-chan *fetchRequestResponse { return f.fetchResponses } // loop is a main fetcher loop, listens for incoming requests/cancellations, forwards outgoing responses. func (f *blocksFetcher) loop() { defer close(f.quit) // Wait for all loop's goroutines to finish, and safely release resources. wg := &sync.WaitGroup{} defer func() { wg.Wait() close(f.fetchResponses) }() // Periodically remove stale peer locks. go func() { ticker := time.NewTicker(peerLocksPollingInterval) defer ticker.Stop() for { select { case <-ticker.C: f.removeStalePeerLocks(peerLockMaxAge) case <-f.ctx.Done(): return } } }() // Main loop. for { // Make sure there is are available peers before processing requests. if _, err := f.waitForMinimumPeers(f.ctx); err != nil { log.Error(err) } select { case <-f.ctx.Done(): log.Debug("Context closed, exiting goroutine (blocks fetcher)") return case req := <-f.fetchRequests: wg.Add(1) go func() { defer wg.Done() select { case <-f.ctx.Done(): case f.fetchResponses <- f.handleRequest(req.ctx, req.start, req.count): } }() } } } // scheduleRequest adds request to incoming queue. func (f *blocksFetcher) scheduleRequest(ctx context.Context, start types.Slot, count uint64) error { if ctx.Err() != nil { return ctx.Err() } request := &fetchRequestParams{ ctx: ctx, start: start, count: count, } select { case <-f.ctx.Done(): return errFetcherCtxIsDone case f.fetchRequests <- request: } return nil } // handleRequest parses fetch request and forwards it to response builder. func (f *blocksFetcher) handleRequest(ctx context.Context, start types.Slot, count uint64) *fetchRequestResponse { ctx, span := trace.StartSpan(ctx, "initialsync.handleRequest") defer span.End() response := &fetchRequestResponse{ start: start, count: count, blocks: []block.SignedBeaconBlock{}, err: nil, } if ctx.Err() != nil { response.err = ctx.Err() return response } _, targetEpoch, peers := f.calculateHeadAndTargetEpochs() if len(peers) == 0 { response.err = errNoPeersAvailable return response } // Short circuit start far exceeding the highest finalized epoch in some infinite loop. if f.mode == modeStopOnFinalizedEpoch { highestFinalizedSlot := params.BeaconConfig().SlotsPerEpoch.Mul(uint64(targetEpoch + 1)) if start > highestFinalizedSlot { response.err = fmt.Errorf("%w, slot: %d, highest finalized slot: %d", errSlotIsTooHigh, start, highestFinalizedSlot) return response } } response.blocks, response.pid, response.err = f.fetchBlocksFromPeer(ctx, start, count, peers) return response } // fetchBlocksFromPeer fetches blocks from a single randomly selected peer. func (f *blocksFetcher) fetchBlocksFromPeer( ctx context.Context, start types.Slot, count uint64, peers []peer.ID, ) ([]block.SignedBeaconBlock, peer.ID, error) { ctx, span := trace.StartSpan(ctx, "initialsync.fetchBlocksFromPeer") defer span.End() peers = f.filterPeers(ctx, peers, peersPercentagePerRequest) req := &p2ppb.BeaconBlocksByRangeRequest{ StartSlot: start, Count: count, Step: 1, } for i := 0; i < len(peers); i++ { if blocks, err := f.requestBlocks(ctx, req, peers[i]); err == nil { f.p2p.Peers().Scorers().BlockProviderScorer().Touch(peers[i]) return blocks, peers[i], err } } return nil, "", errNoPeersAvailable } // requestBlocks is a wrapper for handling BeaconBlocksByRangeRequest requests/streams. func (f *blocksFetcher) requestBlocks( ctx context.Context, req *p2ppb.BeaconBlocksByRangeRequest, pid peer.ID, ) ([]block.SignedBeaconBlock, error) { if ctx.Err() != nil { return nil, ctx.Err() } l := f.peerLock(pid) l.Lock() log.WithFields(logrus.Fields{ "peer": pid, "start": req.StartSlot, "count": req.Count, "step": req.Step, "capacity": f.rateLimiter.Remaining(pid.String()), "score": f.p2p.Peers().Scorers().BlockProviderScorer().FormatScorePretty(pid), }).Debug("Requesting blocks") if f.rateLimiter.Remaining(pid.String()) < int64(req.Count) { if err := f.waitForBandwidth(pid); err != nil { return nil, err } } f.rateLimiter.Add(pid.String(), int64(req.Count)) l.Unlock() return prysmsync.SendBeaconBlocksByRangeRequest(ctx, f.chain, f.p2p, pid, req, nil) } // requestBlocksByRoot is a wrapper for handling BeaconBlockByRootsReq requests/streams. func (f *blocksFetcher) requestBlocksByRoot( ctx context.Context, req *p2pTypes.BeaconBlockByRootsReq, pid peer.ID, ) ([]block.SignedBeaconBlock, error) { if ctx.Err() != nil { return nil, ctx.Err() } l := f.peerLock(pid) l.Lock() log.WithFields(logrus.Fields{ "peer": pid, "numRoots": len(*req), "capacity": f.rateLimiter.Remaining(pid.String()), "score": f.p2p.Peers().Scorers().BlockProviderScorer().FormatScorePretty(pid), }).Debug("Requesting blocks (by roots)") if f.rateLimiter.Remaining(pid.String()) < int64(len(*req)) { if err := f.waitForBandwidth(pid); err != nil { return nil, err } } f.rateLimiter.Add(pid.String(), int64(len(*req))) l.Unlock() return prysmsync.SendBeaconBlocksByRootRequest(ctx, f.chain, f.p2p, pid, req, nil) } // waitForBandwidth blocks up until peer's bandwidth is restored. func (f *blocksFetcher) waitForBandwidth(pid peer.ID) error { log.WithField("peer", pid).Debug("Slowing down for rate limit") timer := time.NewTimer(f.rateLimiter.TillEmpty(pid.String())) defer timer.Stop() select { case <-f.ctx.Done(): return errFetcherCtxIsDone case <-timer.C: // Peer has gathered enough capacity to be polled again. } return nil }