// Copyright 2019 The Waku Library Authors. // // The Waku 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 Waku library is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty off // 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 Waku library. If not, see . // // This software uses the go-ethereum library, which is licensed // under the GNU Lesser General Public Library, version 3 or any later. package waku import ( "bytes" "fmt" "math" "sync" "time" mapset "github.com/deckarep/golang-set" "go.uber.org/zap" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/crypto" "github.com/ethereum/go-ethereum/p2p" "github.com/ethereum/go-ethereum/rlp" ) // Peer represents a waku protocol peer connection. type Peer struct { host *Waku peer *p2p.Peer ws p2p.MsgReadWriter logger *zap.Logger trusted bool powRequirement float64 // bloomMu is to allow thread safe access to // the bloom filter bloomMu sync.Mutex bloomFilter []byte // topicInterestMu is to allow thread safe access to // the map of topic interests topicInterestMu sync.Mutex topicInterest map[TopicType]bool // fullNode is used to indicate that the node will be accepting any // envelope. The opposite is an "empty node" , which is when // a bloom filter is all 0s or topic interest is an empty map (not nil). // In that case no envelope is accepted. fullNode bool confirmationsEnabled bool rateLimitsMu sync.Mutex rateLimits RateLimits known mapset.Set // Messages already known by the peer to avoid wasting bandwidth quit chan struct{} } // newPeer creates a new waku peer object, but does not run the handshake itself. func newPeer(host *Waku, remote *p2p.Peer, rw p2p.MsgReadWriter, logger *zap.Logger) *Peer { if logger == nil { logger = zap.NewNop() } return &Peer{ host: host, peer: remote, ws: rw, logger: logger, trusted: false, powRequirement: 0.0, known: mapset.NewSet(), quit: make(chan struct{}), bloomFilter: MakeFullNodeBloom(), fullNode: true, } } // start initiates the peer updater, periodically broadcasting the waku packets // into the network. func (p *Peer) start() { go p.update() p.logger.Debug("starting peer", zap.Binary("peerID", p.ID())) } // stop terminates the peer updater, stopping message forwarding to it. func (p *Peer) stop() { close(p.quit) p.logger.Debug("stopping peer", zap.Binary("peerID", p.ID())) } // handshake sends the protocol initiation status message to the remote peer and // verifies the remote status too. func (p *Peer) handshake() error { // Send the handshake status message asynchronously errc := make(chan error, 1) opts := p.host.toStatusOptions() go func() { errc <- p2p.SendItems(p.ws, statusCode, ProtocolVersion, opts) }() // Fetch the remote status packet and verify protocol match packet, err := p.ws.ReadMsg() if err != nil { return err } if packet.Code != statusCode { return fmt.Errorf("p [%x] sent packet %x before status packet", p.ID(), packet.Code) } var ( peerProtocolVersion uint64 peerOptions statusOptions ) s := rlp.NewStream(packet.Payload, uint64(packet.Size)) if _, err := s.List(); err != nil { return fmt.Errorf("p [%x]: failed to decode status packet: %v", p.ID(), err) } // Validate protocol version. if err := s.Decode(&peerProtocolVersion); err != nil { return fmt.Errorf("p [%x]: failed to decode peer protocol version: %v", p.ID(), err) } if peerProtocolVersion != ProtocolVersion { return fmt.Errorf("p [%x]: protocol version mismatch %d != %d", p.ID(), peerProtocolVersion, ProtocolVersion) } // Decode and validate other status packet options. if err := s.Decode(&peerOptions); err != nil { return fmt.Errorf("p [%x]: failed to decode status options: %v", p.ID(), err) } if err := s.ListEnd(); err != nil { return fmt.Errorf("p [%x]: failed to decode status packet: %v", p.ID(), err) } if err := p.setOptions(peerOptions.WithDefaults()); err != nil { return fmt.Errorf("p [%x]: failed to set options: %v", p.ID(), err) } if err := <-errc; err != nil { return fmt.Errorf("p [%x] failed to send status packet: %v", p.ID(), err) } return nil } func (p *Peer) setOptions(peerOptions statusOptions) error { p.logger.Debug("settings options", zap.Binary("peerID", p.ID()), zap.Any("Options", peerOptions)) if err := peerOptions.Validate(); err != nil { return fmt.Errorf("p [%x]: sent invalid options: %v", p.ID(), err) } // Validate and save peer's PoW. pow := peerOptions.PoWRequirementF() if pow != nil { if math.IsInf(*pow, 0) || math.IsNaN(*pow) || *pow < 0.0 { return fmt.Errorf("p [%x]: sent bad status message: invalid pow", p.ID()) } p.powRequirement = *pow } if peerOptions.TopicInterest != nil { p.setTopicInterest(peerOptions.TopicInterest) } else if peerOptions.BloomFilter != nil { // Validate and save peer's bloom filters. bloom := peerOptions.BloomFilter bloomSize := len(bloom) if bloomSize != 0 && bloomSize != BloomFilterSize { return fmt.Errorf("p [%x] sent bad status message: wrong bloom filter size %d", p.ID(), bloomSize) } p.setBloomFilter(bloom) } if peerOptions.LightNodeEnabled != nil { // Validate and save other peer's options. if *peerOptions.LightNodeEnabled && p.host.LightClientMode() && p.host.LightClientModeConnectionRestricted() { return fmt.Errorf("p [%x] is useless: two light client communication restricted", p.ID()) } } if peerOptions.ConfirmationsEnabled != nil { p.confirmationsEnabled = *peerOptions.ConfirmationsEnabled } if peerOptions.RateLimits != nil { p.setRateLimits(*peerOptions.RateLimits) } return nil } // update executes periodic operations on the peer, including message transmission // and expiration. func (p *Peer) update() { // Start the tickers for the updates expire := time.NewTicker(expirationCycle) transmit := time.NewTicker(transmissionCycle) // Loop and transmit until termination is requested for { select { case <-expire.C: p.expire() case <-transmit.C: if err := p.broadcast(); err != nil { p.logger.Debug("broadcasting failed", zap.Binary("peer", p.ID()), zap.Error(err)) return } case <-p.quit: return } } } // mark marks an envelope known to the peer so that it won't be sent back. func (p *Peer) mark(envelope *Envelope) { p.known.Add(envelope.Hash()) } // marked checks if an envelope is already known to the remote peer. func (p *Peer) marked(envelope *Envelope) bool { return p.known.Contains(envelope.Hash()) } // expire iterates over all the known envelopes in the host and removes all // expired (unknown) ones from the known list. func (p *Peer) expire() { unmark := make(map[common.Hash]struct{}) p.known.Each(func(v interface{}) bool { if !p.host.isEnvelopeCached(v.(common.Hash)) { unmark[v.(common.Hash)] = struct{}{} } return true }) // Dump all known but no longer cached for hash := range unmark { p.known.Remove(hash) } } // broadcast iterates over the collection of envelopes and transmits yet unknown // ones over the network. func (p *Peer) broadcast() error { envelopes := p.host.Envelopes() bundle := make([]*Envelope, 0, len(envelopes)) for _, envelope := range envelopes { if !p.marked(envelope) && envelope.PoW() >= p.powRequirement && p.topicOrBloomMatch(envelope) { bundle = append(bundle, envelope) } } if len(bundle) == 0 { return nil } batchHash, err := sendBundle(p.ws, bundle) if err != nil { p.logger.Debug("failed to deliver envelopes", zap.Binary("peer", p.ID()), zap.Error(err)) return err } // mark envelopes only if they were successfully sent for _, e := range bundle { p.mark(e) event := EnvelopeEvent{ Event: EventEnvelopeSent, Hash: e.Hash(), Peer: p.peer.ID(), } if p.confirmationsEnabled { event.Batch = batchHash } p.host.envelopeFeed.Send(event) } p.logger.Debug("broadcasted bundles successfully", zap.Binary("peer", p.ID()), zap.Int("count", len(bundle))) return nil } // ID returns a peer's id func (p *Peer) ID() []byte { id := p.peer.ID() return id[:] } func (p *Peer) notifyAboutPowRequirementChange(pow float64) error { i := math.Float64bits(pow) return p2p.Send(p.ws, statusUpdateCode, statusOptions{PoWRequirement: &i}) } func (p *Peer) notifyAboutBloomFilterChange(bloom []byte) error { return p2p.Send(p.ws, statusUpdateCode, statusOptions{BloomFilter: bloom}) } func (p *Peer) notifyAboutTopicInterestChange(topics []TopicType) error { return p2p.Send(p.ws, statusUpdateCode, statusOptions{TopicInterest: topics}) } func (p *Peer) bloomMatch(env *Envelope) bool { p.bloomMu.Lock() defer p.bloomMu.Unlock() return p.fullNode || BloomFilterMatch(p.bloomFilter, env.Bloom()) } func (p *Peer) topicInterestMatch(env *Envelope) bool { p.topicInterestMu.Lock() defer p.topicInterestMu.Unlock() if p.topicInterest == nil { return false } return p.topicInterest[env.Topic] } // topicOrBloomMatch matches against topic-interest if topic interest // is not nil. Otherwise it will match against the bloom-filter. // If the bloom-filter is nil, or full, the node is considered a full-node // and any envelope will be accepted. An empty topic-interest (but not nil) // signals that we are not interested in any envelope. func (p *Peer) topicOrBloomMatch(env *Envelope) bool { p.topicInterestMu.Lock() topicInterestMode := p.topicInterest != nil p.topicInterestMu.Unlock() if topicInterestMode { return p.topicInterestMatch(env) } return p.bloomMatch(env) } func (p *Peer) setBloomFilter(bloom []byte) { p.bloomMu.Lock() defer p.bloomMu.Unlock() p.bloomFilter = bloom p.fullNode = isFullNode(bloom) if p.fullNode && p.bloomFilter == nil { p.bloomFilter = MakeFullNodeBloom() } p.topicInterest = nil } func (p *Peer) setTopicInterest(topicInterest []TopicType) { p.topicInterestMu.Lock() defer p.topicInterestMu.Unlock() if topicInterest == nil { p.topicInterest = nil return } p.topicInterest = make(map[TopicType]bool) for _, topic := range topicInterest { p.topicInterest[topic] = true } p.fullNode = false p.bloomFilter = nil } func (p *Peer) setRateLimits(r RateLimits) { p.rateLimitsMu.Lock() p.rateLimits = r p.rateLimitsMu.Unlock() } func MakeFullNodeBloom() []byte { bloom := make([]byte, BloomFilterSize) for i := 0; i < BloomFilterSize; i++ { bloom[i] = 0xFF } return bloom } func sendBundle(rw p2p.MsgWriter, bundle []*Envelope) (rst common.Hash, err error) { data, err := rlp.EncodeToBytes(bundle) if err != nil { return } err = rw.WriteMsg(p2p.Msg{ Code: messagesCode, Size: uint32(len(data)), Payload: bytes.NewBuffer(data), }) if err != nil { return } return crypto.Keccak256Hash(data), nil }