// 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" "crypto/ecdsa" "crypto/sha256" "errors" "fmt" "runtime" "sync" "time" "github.com/ethereum/go-ethereum/common/hexutil" "go.uber.org/zap" mapset "github.com/deckarep/golang-set" "golang.org/x/crypto/pbkdf2" gethcommon "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/crypto" "github.com/ethereum/go-ethereum/event" "github.com/ethereum/go-ethereum/p2p" "github.com/ethereum/go-ethereum/p2p/enode" "github.com/ethereum/go-ethereum/rlp" "github.com/ethereum/go-ethereum/rpc" "github.com/status-im/status-go/eth-node/types" "github.com/status-im/status-go/logutils" "github.com/status-im/status-go/waku/common" v0 "github.com/status-im/status-go/waku/v0" v1 "github.com/status-im/status-go/waku/v1" ) const messageQueueLimit = 1024 type Bridge interface { Pipe() (<-chan *common.Envelope, chan<- *common.Envelope) } type settings struct { MaxMsgSize uint32 // Maximal message length allowed by the waku node EnableConfirmations bool // Enable sending message confirmations MinPow float64 // Minimal PoW required by the waku node MinPowTolerance float64 // Minimal PoW tolerated by the waku node for a limited time BloomFilter []byte // Bloom filter for topics of interest for this node BloomFilterTolerance []byte // Bloom filter tolerated by the waku node for a limited time TopicInterest map[common.TopicType]bool // Topic interest for this node TopicInterestTolerance map[common.TopicType]bool // Topic interest tolerated by the waku node for a limited time SoftBlacklistedPeerIDs map[string]bool // SoftBlacklistedPeerIDs is a list of peer ids that we want to keep connected but silently drop any envelope from BloomFilterMode bool // Whether we should match against bloom-filter only LightClient bool // Light client mode enabled does not forward messages RestrictLightClientsConn bool // Restrict connection between two light clients SyncAllowance int // Maximum time in seconds allowed to process the waku-related messages FullNode bool // Whether this is to be run in FullNode settings } // Waku represents a dark communication interface through the Ethereum // network, using its very own P2P communication layer. type Waku struct { protocols []p2p.Protocol // Peer description and parameters filters *common.Filters // Message filters installed with Subscribe function privateKeys map[string]*ecdsa.PrivateKey // Private key storage symKeys map[string][]byte // Symmetric key storage keyMu sync.RWMutex // Mutex associated with key stores envelopes map[gethcommon.Hash]*common.Envelope // Pool of envelopes currently tracked by this node expirations map[uint32]mapset.Set // Message expiration pool poolMu sync.RWMutex // Mutex to sync the message and expiration pools stats *common.StatsTracker peers map[common.Peer]struct{} // Set of currently active peers peerMu sync.RWMutex // Mutex to sync the active peer set msgQueue chan *common.Envelope // Message queue for normal waku messages p2pMsgQueue chan interface{} // Message queue for peer-to-peer messages (not to be forwarded any further) and history delivery confirmations. p2pMsgIDs map[gethcommon.Hash]bool // Map of the currently processing ids p2pMsgIDsMu sync.RWMutex quit chan struct{} // Channel used for graceful exit settings settings // Holds configuration settings that can be dynamically changed settingsMu sync.RWMutex // Mutex to sync the settings access mailServer MailServer rateLimiter *common.PeerRateLimiter envelopeFeed event.Feed timeSource func() time.Time // source of time for waku bridge Bridge bridgeWg sync.WaitGroup cancelBridge chan struct{} logger *zap.Logger } // New creates a Waku client ready to communicate through the Ethereum P2P network. func New(cfg *Config, logger *zap.Logger) *Waku { if logger == nil { logger = logutils.ZapLogger() } logger.Debug("starting waku with config", zap.Any("config", cfg)) if cfg == nil { c := DefaultConfig cfg = &c } waku := &Waku{ privateKeys: make(map[string]*ecdsa.PrivateKey), symKeys: make(map[string][]byte), envelopes: make(map[gethcommon.Hash]*common.Envelope), expirations: make(map[uint32]mapset.Set), peers: make(map[common.Peer]struct{}), msgQueue: make(chan *common.Envelope, messageQueueLimit), p2pMsgQueue: make(chan interface{}, messageQueueLimit), p2pMsgIDs: make(map[gethcommon.Hash]bool), quit: make(chan struct{}), timeSource: time.Now, logger: logger, } waku.settings = settings{ MaxMsgSize: cfg.MaxMessageSize, MinPow: cfg.MinimumAcceptedPoW, MinPowTolerance: cfg.MinimumAcceptedPoW, EnableConfirmations: cfg.EnableConfirmations, LightClient: cfg.LightClient, FullNode: cfg.FullNode, BloomFilterMode: cfg.BloomFilterMode, SoftBlacklistedPeerIDs: make(map[string]bool), RestrictLightClientsConn: cfg.RestrictLightClientsConn, SyncAllowance: common.DefaultSyncAllowance, } for _, peerID := range cfg.SoftBlacklistedPeerIDs { waku.settings.SoftBlacklistedPeerIDs[peerID] = true } if cfg.FullNode { waku.settings.BloomFilter = common.MakeFullNodeBloom() waku.settings.BloomFilterTolerance = common.MakeFullNodeBloom() } waku.filters = common.NewFilters() waku.stats = &common.StatsTracker{} // p2p waku sub-protocol handler waku.protocols = []p2p.Protocol{{ Name: v0.Name, Version: uint(v0.Version), Length: v0.NumberOfMessageCodes, Run: waku.handlePeerV0, NodeInfo: func() interface{} { return map[string]interface{}{ "version": v0.VersionStr, "maxMessageSize": waku.MaxMessageSize(), "minimumPoW": waku.MinPow(), } }, }, { Name: v1.Name, Version: uint(v1.Version), Length: v1.NumberOfMessageCodes, Run: waku.handlePeerV1, NodeInfo: func() interface{} { return map[string]interface{}{ "version": v1.VersionStr, "maxMessageSize": waku.MaxMessageSize(), "minimumPoW": waku.MinPow(), } }, }, } return waku } func (w *Waku) GetStats() types.StatsSummary { return w.stats.GetStats() } // MinPow returns the PoW value required by this node. func (w *Waku) MinPow() float64 { w.settingsMu.RLock() defer w.settingsMu.RUnlock() return w.settings.MinPow } // SetMinimumPoW sets the minimal PoW required by this node func (w *Waku) SetMinimumPoW(val float64, tolerate bool) error { if val < 0.0 { return fmt.Errorf("invalid PoW: %f", val) } w.settingsMu.Lock() w.settings.MinPow = val w.settingsMu.Unlock() w.notifyPeersAboutPowRequirementChange(val) if tolerate { go func() { // allow some time before all the peers have processed the notification select { case <-w.quit: return case <-time.After(time.Duration(w.settings.SyncAllowance) * time.Second): w.settingsMu.Lock() w.settings.MinPowTolerance = val w.settingsMu.Unlock() } }() } return nil } // MinPowTolerance returns the value of minimum PoW which is tolerated for a limited // time after PoW was changed. If sufficient time have elapsed or no change of PoW // have ever occurred, the return value will be the same as return value of MinPow(). func (w *Waku) MinPowTolerance() float64 { w.settingsMu.RLock() defer w.settingsMu.RUnlock() return w.settings.MinPowTolerance } // BloomFilter returns the aggregated bloom filter for all the topics of interest. // The nodes are required to send only messages that match the advertised bloom filter. // If a message does not match the bloom, it will tantamount to spam, and the peer will // be disconnected. func (w *Waku) BloomFilter() []byte { if w.FullNode() { return common.MakeFullNodeBloom() } w.settingsMu.RLock() defer w.settingsMu.RUnlock() return w.settings.BloomFilter } // BloomFilterTolerance returns the bloom filter which is tolerated for a limited // time after new bloom was advertised to the peers. If sufficient time have elapsed // or no change of bloom filter have ever occurred, the return value will be the same // as return value of BloomFilter(). func (w *Waku) BloomFilterTolerance() []byte { if w.FullNode() { return common.MakeFullNodeBloom() } w.settingsMu.RLock() defer w.settingsMu.RUnlock() return w.settings.BloomFilterTolerance } // BloomFilterMode returns whether the node is running in bloom filter mode func (w *Waku) BloomFilterMode() bool { if w.FullNode() { return true } w.settingsMu.RLock() defer w.settingsMu.RUnlock() return w.settings.BloomFilterMode } // SetBloomFilter sets the new bloom filter func (w *Waku) SetBloomFilter(bloom []byte) error { if len(bloom) != common.BloomFilterSize { return fmt.Errorf("invalid bloom filter size: %d", len(bloom)) } b := make([]byte, common.BloomFilterSize) copy(b, bloom) w.settingsMu.Lock() w.settings.BloomFilter = b // Setting bloom filter reset topic interest w.settings.TopicInterest = nil w.settingsMu.Unlock() w.notifyPeersAboutBloomFilterChange(b) go func() { // allow some time before all the peers have processed the notification select { case <-w.quit: return case <-time.After(time.Duration(w.settings.SyncAllowance) * time.Second): w.settingsMu.Lock() w.settings.BloomFilterTolerance = b w.settingsMu.Unlock() } }() return nil } // TopicInterest returns the all the topics of interest. // The nodes are required to send only messages that match the advertised topics. // If a message does not match the topic-interest, it will tantamount to spam, and the peer will // be disconnected. func (w *Waku) TopicInterest() []common.TopicType { w.settingsMu.RLock() defer w.settingsMu.RUnlock() // Return nil if FullNode as otherwise topic interest will have precedence if w.settings.FullNode || w.settings.TopicInterest == nil { return nil } topicInterest := make([]common.TopicType, len(w.settings.TopicInterest)) i := 0 for topic := range w.settings.TopicInterest { topicInterest[i] = topic i++ } return topicInterest } // updateTopicInterest adds a new topic interest // and informs the peers func (w *Waku) updateTopicInterest(f *common.Filter) error { newTopicInterest := w.TopicInterest() for _, t := range f.Topics { top := common.BytesToTopic(t) newTopicInterest = append(newTopicInterest, top) } return w.SetTopicInterest(newTopicInterest) } // SetTopicInterest sets the new topicInterest func (w *Waku) SetTopicInterest(topicInterest []common.TopicType) error { var topicInterestMap map[common.TopicType]bool if len(topicInterest) > common.MaxTopicInterest { return fmt.Errorf("invalid topic interest: %d", len(topicInterest)) } if topicInterest != nil { topicInterestMap = make(map[common.TopicType]bool, len(topicInterest)) for _, topic := range topicInterest { topicInterestMap[topic] = true } } w.settingsMu.Lock() w.settings.TopicInterest = topicInterestMap // Setting topic interest resets bloom filter w.settings.BloomFilter = nil w.settingsMu.Unlock() w.notifyPeersAboutTopicInterestChange(topicInterest) go func() { // allow some time before all the peers have processed the notification select { case <-w.quit: return case <-time.After(time.Duration(w.settings.SyncAllowance) * time.Second): w.settingsMu.Lock() w.settings.TopicInterestTolerance = topicInterestMap w.settingsMu.Unlock() } }() return nil } // MaxMessageSize returns the maximum accepted message size. func (w *Waku) MaxMessageSize() uint32 { w.settingsMu.RLock() defer w.settingsMu.RUnlock() return w.settings.MaxMsgSize } // SetMaxMessageSize sets the maximal message size allowed by this node func (w *Waku) SetMaxMessageSize(size uint32) error { if size > common.MaxMessageSize { return fmt.Errorf("message size too large [%d>%d]", size, common.MaxMessageSize) } w.settingsMu.Lock() w.settings.MaxMsgSize = size w.settingsMu.Unlock() return nil } // LightClientMode indicates is this node is light client (does not forward any messages) func (w *Waku) LightClientMode() bool { w.settingsMu.RLock() defer w.settingsMu.RUnlock() return w.settings.LightClient } // SetLightClientMode makes node light client (does not forward any messages) func (w *Waku) SetLightClientMode(v bool) { w.settingsMu.Lock() w.settings.LightClient = v w.settingsMu.Unlock() } // LightClientModeConnectionRestricted indicates that connection to light client in light client mode not allowed func (w *Waku) LightClientModeConnectionRestricted() bool { w.settingsMu.RLock() defer w.settingsMu.RUnlock() return w.settings.RestrictLightClientsConn } // PacketRateLimiting returns RateLimits information for packets func (w *Waku) PacketRateLimits() common.RateLimits { if w.rateLimiter == nil { return common.RateLimits{} } return common.RateLimits{ IPLimits: uint64(w.rateLimiter.PacketLimitPerSecIP), PeerIDLimits: uint64(w.rateLimiter.PacketLimitPerSecPeerID), } } // BytesRateLimiting returns RateLimits information for bytes func (w *Waku) BytesRateLimits() common.RateLimits { if w.rateLimiter == nil { return common.RateLimits{} } return common.RateLimits{ IPLimits: uint64(w.rateLimiter.BytesLimitPerSecIP), PeerIDLimits: uint64(w.rateLimiter.BytesLimitPerSecPeerID), } } // ConfirmationsEnabled returns true if message confirmations are enabled. func (w *Waku) ConfirmationsEnabled() bool { w.settingsMu.RLock() defer w.settingsMu.RUnlock() return w.settings.EnableConfirmations } // CurrentTime returns current time. func (w *Waku) CurrentTime() time.Time { return w.timeSource() } // SetTimeSource assigns a particular source of time to a waku object. func (w *Waku) SetTimeSource(timesource func() time.Time) { w.timeSource = timesource } // APIs returns the RPC descriptors the Waku implementation offers func (w *Waku) APIs() []rpc.API { return []rpc.API{ { Namespace: v0.Name, Version: v0.VersionStr, Service: NewPublicWakuAPI(w), Public: false, }, } } // Protocols returns the waku sub-protocols ran by this particular client. func (w *Waku) Protocols() []p2p.Protocol { return w.protocols } // RegisterMailServer registers MailServer interface. // MailServer will process all the incoming messages with p2pRequestCode. func (w *Waku) RegisterMailServer(server MailServer) { w.mailServer = server } // SetRateLimiter registers a rate limiter. func (w *Waku) RegisterRateLimiter(r *common.PeerRateLimiter) { w.rateLimiter = r } // RegisterBridge registers a new Bridge that moves envelopes // between different subprotocols. // It's important that a bridge is registered before the service // is started, otherwise, it won't read and propagate envelopes. func (w *Waku) RegisterBridge(b Bridge) { if w.cancelBridge != nil { close(w.cancelBridge) } w.bridge = b w.cancelBridge = make(chan struct{}) w.bridgeWg.Add(1) go w.readBridgeLoop() } func (w *Waku) readBridgeLoop() { defer w.bridgeWg.Done() out, _ := w.bridge.Pipe() for { select { case <-w.cancelBridge: return case env := <-out: _, err := w.addAndBridge(env, false, true) if err != nil { common.BridgeReceivedFailed.Inc() w.logger.Warn( "failed to add a bridged envelope", zap.Binary("ID", env.Hash().Bytes()), zap.Error(err), ) } else { common.BridgeReceivedSucceed.Inc() w.logger.Debug("bridged envelope successfully", zap.Binary("ID", env.Hash().Bytes())) w.envelopeFeed.Send(common.EnvelopeEvent{ Event: common.EventEnvelopeReceived, Topic: env.Topic, Hash: env.Hash(), }) } } } } func (w *Waku) SendEnvelopeEvent(event common.EnvelopeEvent) int { return w.envelopeFeed.Send(event) } // SubscribeEnvelopeEvents subscribes to envelopes feed. // In order to prevent blocking waku producers events must be amply buffered. func (w *Waku) SubscribeEnvelopeEvents(events chan<- common.EnvelopeEvent) event.Subscription { return w.envelopeFeed.Subscribe(events) } func (w *Waku) notifyPeersAboutPowRequirementChange(pow float64) { arr := w.getPeers() for _, p := range arr { err := p.NotifyAboutPowRequirementChange(pow) if err != nil { // allow one retry err = p.NotifyAboutPowRequirementChange(pow) } if err != nil { w.logger.Warn("failed to notify peer about new pow requirement", zap.Binary("peer", p.ID()), zap.Error(err)) } } } func (w *Waku) FullNode() bool { w.settingsMu.RLock() // If full node, nothing to do fullNode := w.settings.FullNode w.settingsMu.RUnlock() return fullNode } func (w *Waku) notifyPeersAboutBloomFilterChange(bloom []byte) { if w.FullNode() { return } arr := w.getPeers() for _, p := range arr { err := p.NotifyAboutBloomFilterChange(bloom) if err != nil { // allow one retry err = p.NotifyAboutBloomFilterChange(bloom) } if err != nil { w.logger.Warn("failed to notify peer about new bloom filter change", zap.Binary("peer", p.ID()), zap.Error(err)) } } } func (w *Waku) notifyPeersAboutTopicInterestChange(topicInterest []common.TopicType) { if w.FullNode() { return } arr := w.getPeers() for _, p := range arr { err := p.NotifyAboutTopicInterestChange(topicInterest) if err != nil { // allow one retry err = p.NotifyAboutTopicInterestChange(topicInterest) } if err != nil { w.logger.Warn("failed to notify peer about new topic interest", zap.Binary("peer", p.ID()), zap.Error(err)) } } } func (w *Waku) getPeers() []common.Peer { w.peerMu.Lock() arr := make([]common.Peer, len(w.peers)) i := 0 for p := range w.peers { arr[i] = p i++ } w.peerMu.Unlock() return arr } // getPeer retrieves peer by ID func (w *Waku) getPeer(peerID []byte) (common.Peer, error) { w.peerMu.Lock() defer w.peerMu.Unlock() for p := range w.peers { if bytes.Equal(peerID, p.ID()) { return p, nil } } return nil, fmt.Errorf("could not find peer with ID: %x", peerID) } // AllowP2PMessagesFromPeer marks specific peer trusted, // which will allow it to send historic (expired) messages. func (w *Waku) AllowP2PMessagesFromPeer(peerID []byte) error { p, err := w.getPeer(peerID) if err != nil { return err } p.SetPeerTrusted(true) return nil } // RequestHistoricMessages sends a message with p2pRequestCode to a specific peer, // which is known to implement MailServer interface, and is supposed to process this // request and respond with a number of peer-to-peer messages (possibly expired), // which are not supposed to be forwarded any further. // The waku protocol is agnostic of the format and contents of envelope. func (w *Waku) RequestHistoricMessages(peerID []byte, envelope *common.Envelope) error { return w.RequestHistoricMessagesWithTimeout(peerID, envelope, 0) } // RequestHistoricMessagesWithTimeout acts as RequestHistoricMessages but requires to pass a timeout. // It sends an event EventMailServerRequestExpired after the timeout. func (w *Waku) RequestHistoricMessagesWithTimeout(peerID []byte, envelope *common.Envelope, timeout time.Duration) error { p, err := w.getPeer(peerID) if err != nil { return err } p.SetPeerTrusted(true) w.envelopeFeed.Send(common.EnvelopeEvent{ Peer: p.EnodeID(), Topic: envelope.Topic, Hash: envelope.Hash(), Event: common.EventMailServerRequestSent, }) err = p.RequestHistoricMessages(envelope) if timeout != 0 { go w.expireRequestHistoricMessages(p.EnodeID(), envelope.Hash(), timeout) } return err } func (w *Waku) SendMessagesRequest(peerID []byte, request common.MessagesRequest) error { if err := request.Validate(); err != nil { return err } p, err := w.getPeer(peerID) if err != nil { return err } p.SetPeerTrusted(true) if err := p.SendMessagesRequest(request); err != nil { return err } w.envelopeFeed.Send(common.EnvelopeEvent{ Peer: p.EnodeID(), Hash: gethcommon.BytesToHash(request.ID), Event: common.EventMailServerRequestSent, }) return nil } func (w *Waku) expireRequestHistoricMessages(peer enode.ID, hash gethcommon.Hash, timeout time.Duration) { timer := time.NewTimer(timeout) defer timer.Stop() select { case <-w.quit: return case <-timer.C: w.envelopeFeed.Send(common.EnvelopeEvent{ Peer: peer, Hash: hash, Event: common.EventMailServerRequestExpired, }) } } func (w *Waku) SendHistoricMessageResponse(peerID []byte, payload []byte) error { peer, err := w.getPeer(peerID) if err != nil { return err } return peer.SendHistoricMessageResponse(payload) } // SendP2PMessage sends a peer-to-peer message to a specific peer. // It sends one or more envelopes in a single batch. func (w *Waku) SendP2PMessages(peerID []byte, envelopes ...*common.Envelope) error { p, err := w.getPeer(peerID) if err != nil { return err } return p.SendP2PMessages(envelopes) } // SendRawP2PDirect sends a peer-to-peer message to a specific peer. // It sends one or more envelopes in a single batch. func (w *Waku) SendRawP2PDirect(peerID []byte, envelopes ...rlp.RawValue) error { p, err := w.getPeer(peerID) if err != nil { return err } return p.SendRawP2PDirect(envelopes) } // NewKeyPair generates a new cryptographic identity for the client, and injects // it into the known identities for message decryption. Returns ID of the new key pair. func (w *Waku) NewKeyPair() (string, error) { key, err := crypto.GenerateKey() if err != nil || !validatePrivateKey(key) { key, err = crypto.GenerateKey() // retry once } if err != nil { return "", err } if !validatePrivateKey(key) { return "", fmt.Errorf("failed to generate valid key") } id, err := toDeterministicID(hexutil.Encode(crypto.FromECDSAPub(&key.PublicKey)), common.KeyIDSize) if err != nil { return "", err } w.keyMu.Lock() defer w.keyMu.Unlock() if w.privateKeys[id] != nil { return "", fmt.Errorf("failed to generate unique ID") } w.privateKeys[id] = key return id, nil } // DeleteKeyPair deletes the specified key if it exists. func (w *Waku) DeleteKeyPair(key string) bool { deterministicID, err := toDeterministicID(key, common.KeyIDSize) if err != nil { return false } w.keyMu.Lock() defer w.keyMu.Unlock() if w.privateKeys[deterministicID] != nil { delete(w.privateKeys, deterministicID) return true } return false } // AddKeyPair imports a asymmetric private key and returns it identifier. func (w *Waku) AddKeyPair(key *ecdsa.PrivateKey) (string, error) { id, err := makeDeterministicID(hexutil.Encode(crypto.FromECDSAPub(&key.PublicKey)), common.KeyIDSize) if err != nil { return "", err } if w.HasKeyPair(id) { return id, nil // no need to re-inject } w.keyMu.Lock() w.privateKeys[id] = key w.keyMu.Unlock() return id, nil } // SelectKeyPair adds cryptographic identity, and makes sure // that it is the only private key known to the node. func (w *Waku) SelectKeyPair(key *ecdsa.PrivateKey) error { id, err := makeDeterministicID(hexutil.Encode(crypto.FromECDSAPub(&key.PublicKey)), common.KeyIDSize) if err != nil { return err } w.keyMu.Lock() defer w.keyMu.Unlock() w.privateKeys = make(map[string]*ecdsa.PrivateKey) // reset key store w.privateKeys[id] = key return nil } // DeleteKeyPairs removes all cryptographic identities known to the node func (w *Waku) DeleteKeyPairs() error { w.keyMu.Lock() defer w.keyMu.Unlock() w.privateKeys = make(map[string]*ecdsa.PrivateKey) return nil } // HasKeyPair checks if the waku node is configured with the private key // of the specified public pair. func (w *Waku) HasKeyPair(id string) bool { deterministicID, err := toDeterministicID(id, common.KeyIDSize) if err != nil { return false } w.keyMu.RLock() defer w.keyMu.RUnlock() return w.privateKeys[deterministicID] != nil } // GetPrivateKey retrieves the private key of the specified identity. func (w *Waku) GetPrivateKey(id string) (*ecdsa.PrivateKey, error) { deterministicID, err := toDeterministicID(id, common.KeyIDSize) if err != nil { return nil, err } w.keyMu.RLock() defer w.keyMu.RUnlock() key := w.privateKeys[deterministicID] if key == nil { return nil, fmt.Errorf("invalid id") } return key, nil } // GenerateSymKey generates a random symmetric key and stores it under id, // which is then returned. Will be used in the future for session key exchange. func (w *Waku) GenerateSymKey() (string, error) { key, err := common.GenerateSecureRandomData(common.AESKeyLength) if err != nil { return "", err } else if !common.ValidateDataIntegrity(key, common.AESKeyLength) { return "", fmt.Errorf("error in GenerateSymKey: crypto/rand failed to generate random data") } id, err := common.GenerateRandomID() if err != nil { return "", fmt.Errorf("failed to generate ID: %s", err) } w.keyMu.Lock() defer w.keyMu.Unlock() if w.symKeys[id] != nil { return "", fmt.Errorf("failed to generate unique ID") } w.symKeys[id] = key return id, nil } // AddSymKey stores the key with a given id. func (w *Waku) AddSymKey(id string, key []byte) (string, error) { deterministicID, err := toDeterministicID(id, common.KeyIDSize) if err != nil { return "", err } w.keyMu.Lock() defer w.keyMu.Unlock() if w.symKeys[deterministicID] != nil { return "", fmt.Errorf("key already exists: %v", id) } w.symKeys[deterministicID] = key return deterministicID, nil } // AddSymKeyDirect stores the key, and returns its id. func (w *Waku) AddSymKeyDirect(key []byte) (string, error) { if len(key) != common.AESKeyLength { return "", fmt.Errorf("wrong key size: %d", len(key)) } id, err := common.GenerateRandomID() if err != nil { return "", fmt.Errorf("failed to generate ID: %s", err) } w.keyMu.Lock() defer w.keyMu.Unlock() if w.symKeys[id] != nil { return "", fmt.Errorf("failed to generate unique ID") } w.symKeys[id] = key return id, nil } // AddSymKeyFromPassword generates the key from password, stores it, and returns its id. func (w *Waku) AddSymKeyFromPassword(password string) (string, error) { id, err := common.GenerateRandomID() if err != nil { return "", fmt.Errorf("failed to generate ID: %s", err) } if w.HasSymKey(id) { return "", fmt.Errorf("failed to generate unique ID") } // kdf should run no less than 0.1 seconds on an average computer, // because it's an once in a session experience derived := pbkdf2.Key([]byte(password), nil, 65356, common.AESKeyLength, sha256.New) w.keyMu.Lock() defer w.keyMu.Unlock() // double check is necessary, because deriveKeyMaterial() is very slow if w.symKeys[id] != nil { return "", fmt.Errorf("critical error: failed to generate unique ID") } w.symKeys[id] = derived return id, nil } // HasSymKey returns true if there is a key associated with the given id. // Otherwise returns false. func (w *Waku) HasSymKey(id string) bool { w.keyMu.RLock() defer w.keyMu.RUnlock() return w.symKeys[id] != nil } // DeleteSymKey deletes the key associated with the name string if it exists. func (w *Waku) DeleteSymKey(id string) bool { w.keyMu.Lock() defer w.keyMu.Unlock() if w.symKeys[id] != nil { delete(w.symKeys, id) return true } return false } // GetSymKey returns the symmetric key associated with the given id. func (w *Waku) GetSymKey(id string) ([]byte, error) { w.keyMu.RLock() defer w.keyMu.RUnlock() if w.symKeys[id] != nil { return w.symKeys[id], nil } return nil, fmt.Errorf("non-existent key ID") } // Subscribe installs a new message handler used for filtering, decrypting // and subsequent storing of incoming messages. func (w *Waku) Subscribe(f *common.Filter) (string, error) { s, err := w.filters.Install(f) if err != nil { return s, err } err = w.updateSettingsForFilter(f) if err != nil { w.filters.Uninstall(s) return s, err } return s, nil } func (w *Waku) updateSettingsForFilter(f *common.Filter) error { w.settingsMu.RLock() topicInterestMode := !w.settings.BloomFilterMode w.settingsMu.RUnlock() if topicInterestMode { err := w.updateTopicInterest(f) if err != nil { return err } } else { err := w.updateBloomFilter(f) if err != nil { return err } } return nil } // updateBloomFilter recalculates the new value of bloom filter, // and informs the peers if necessary. func (w *Waku) updateBloomFilter(f *common.Filter) error { aggregate := make([]byte, common.BloomFilterSize) for _, t := range f.Topics { top := common.BytesToTopic(t) b := top.ToBloom() aggregate = addBloom(aggregate, b) } if !common.BloomFilterMatch(w.BloomFilter(), aggregate) { // existing bloom filter must be updated aggregate = addBloom(w.BloomFilter(), aggregate) return w.SetBloomFilter(aggregate) } return nil } // GetFilter returns the filter by id. func (w *Waku) GetFilter(id string) *common.Filter { return w.filters.Get(id) } // Unsubscribe removes an installed message handler. // TODO: This does not update the bloom filter, but does update // the topic interest map func (w *Waku) Unsubscribe(id string) error { ok := w.filters.Uninstall(id) if !ok { return fmt.Errorf("failed to unsubscribe: invalid ID '%s'", id) } if !w.settings.BloomFilterMode { return w.SetTopicInterest(w.filters.AllTopics()) } return nil } // Unsubscribe removes an installed message handler. // TODO: This does not update the bloom filter, but does update // the topic interest map func (w *Waku) UnsubscribeMany(ids []string) error { for _, id := range ids { w.logger.Debug("cleaning up filter", zap.String("id", id)) ok := w.filters.Uninstall(id) if !ok { w.logger.Warn("could not remove filter with id", zap.String("id", id)) } } if !w.settings.BloomFilterMode { return w.SetTopicInterest(w.filters.AllTopics()) } return nil } // Send injects a message into the waku send queue, to be distributed in the // network in the coming cycles. func (w *Waku) Send(envelope *common.Envelope) error { w.logger.Debug("send: sending envelope", zap.String("hash", envelope.Hash().String())) ok, err := w.add(envelope, false) if err == nil && !ok { return fmt.Errorf("failed to add envelope") } return err } // Start implements node.Service, starting the background data propagation thread // of the Waku protocol. func (w *Waku) Start() error { go w.update() numCPU := runtime.NumCPU() for i := 0; i < numCPU; i++ { go w.processQueue() } go w.processP2P() return nil } // Stop implements node.Service, stopping the background data propagation thread // of the Waku protocol. func (w *Waku) Stop() error { if w.cancelBridge != nil { close(w.cancelBridge) w.cancelBridge = nil w.bridgeWg.Wait() } close(w.quit) return nil } func (w *Waku) handlePeerV0(p2pPeer *p2p.Peer, rw p2p.MsgReadWriter) error { return w.HandlePeer(v0.NewPeer(w, p2pPeer, rw, w.logger.Named("waku/peerv0"), w.stats), rw) } func (w *Waku) handlePeerV1(p2pPeer *p2p.Peer, rw p2p.MsgReadWriter) error { return w.HandlePeer(v1.NewPeer(w, p2pPeer, rw, w.logger.Named("waku/peerv1"), w.stats), rw) } // HandlePeer is called by the underlying P2P layer when the waku sub-protocol // connection is negotiated. func (w *Waku) HandlePeer(peer common.Peer, rw p2p.MsgReadWriter) error { w.peerMu.Lock() w.peers[peer] = struct{}{} w.peerMu.Unlock() w.logger.Info("handling peer", zap.String("peerID", types.EncodeHex(peer.ID()))) defer func() { w.peerMu.Lock() delete(w.peers, peer) w.peerMu.Unlock() }() if err := peer.Start(); err != nil { return err } defer peer.Stop() if w.rateLimiter != nil { runLoop := func(out p2p.MsgReadWriter) error { peer.SetRWWriter(out) err := peer.Run() w.logger.Info("handled peer", zap.String("peerID", types.EncodeHex(peer.ID())), zap.Error(err)) return err } return w.rateLimiter.Decorate(peer, rw, runLoop) } err := peer.Run() w.logger.Info("handled peer", zap.String("peerID", types.EncodeHex(peer.ID())), zap.Error(err)) return err } func (w *Waku) softBlacklisted(peerID string) bool { w.settingsMu.RLock() defer w.settingsMu.RUnlock() return w.settings.SoftBlacklistedPeerIDs[peerID] } func (w *Waku) OnNewEnvelopes(envelopes []*common.Envelope, peer common.Peer) ([]common.EnvelopeError, error) { envelopeErrors := make([]common.EnvelopeError, 0) peerID := types.EncodeHex(peer.ID()) w.logger.Debug("received new envelopes", zap.Int("count", len(envelopes)), zap.String("peer", peerID)) trouble := false if w.softBlacklisted(peerID) { w.logger.Debug("peer is soft blacklisted", zap.String("peer", peerID)) return nil, nil } for _, env := range envelopes { w.logger.Debug("received new envelope", zap.String("peer", peerID), zap.String("hash", env.Hash().Hex())) cached, err := w.add(env, w.LightClientMode()) if err != nil { _, isTimeSyncError := err.(common.TimeSyncError) if !isTimeSyncError { trouble = true w.logger.Info("invalid envelope received", zap.String("peer", types.EncodeHex(peer.ID())), zap.Error(err)) } envelopeErrors = append(envelopeErrors, common.ErrorToEnvelopeError(env.Hash(), err)) } else if cached { peer.Mark(env) } w.envelopeFeed.Send(common.EnvelopeEvent{ Event: common.EventEnvelopeReceived, Topic: env.Topic, Hash: env.Hash(), Peer: peer.EnodeID(), }) common.EnvelopesValidatedCounter.Inc() } if trouble { return envelopeErrors, errors.New("received invalid envelope") } return envelopeErrors, nil } func (w *Waku) OnNewP2PEnvelopes(envelopes []*common.Envelope) error { for _, envelope := range envelopes { w.postP2P(envelope) } return nil } func (w *Waku) Mailserver() bool { return w.mailServer != nil } func (w *Waku) OnMessagesRequest(request common.MessagesRequest, p common.Peer) error { w.mailServer.Deliver(p.ID(), request) return nil } func (w *Waku) OnDeprecatedMessagesRequest(request *common.Envelope, p common.Peer) error { w.mailServer.DeliverMail(p.ID(), request) return nil } func (w *Waku) OnP2PRequestCompleted(payload []byte, p common.Peer) error { msEvent, err := CreateMailServerEvent(p.EnodeID(), payload) if err != nil { return fmt.Errorf("invalid p2p request complete payload: %v", err) } w.postP2P(*msEvent) return nil } func (w *Waku) OnMessagesResponse(response common.MessagesResponse, p common.Peer) error { w.envelopeFeed.Send(common.EnvelopeEvent{ Batch: response.Hash, Event: common.EventBatchAcknowledged, Peer: p.EnodeID(), Data: response.Errors, }) return nil } func (w *Waku) OnBatchAcknowledged(batchHash gethcommon.Hash, p common.Peer) error { w.envelopeFeed.Send(common.EnvelopeEvent{ Batch: batchHash, Event: common.EventBatchAcknowledged, Peer: p.EnodeID(), }) return nil } func (w *Waku) add(envelope *common.Envelope, isP2P bool) (bool, error) { return w.addAndBridge(envelope, isP2P, false) } func (w *Waku) bloomMatch(envelope *common.Envelope) (bool, error) { if !common.BloomFilterMatch(w.BloomFilter(), envelope.Bloom()) { // maybe the value was recently changed, and the peers did not adjust yet. // in this case the previous value is retrieved by BloomFilterTolerance() // for a short period of peer synchronization. if !common.BloomFilterMatch(w.BloomFilterTolerance(), envelope.Bloom()) { common.EnvelopesCacheFailedCounter.WithLabelValues("no_bloom_match").Inc() return false, fmt.Errorf("envelope does not match bloom filter, hash=[%v], bloom: \n%x \n%x \n%x", envelope.Hash().Hex(), w.BloomFilter(), envelope.Bloom(), envelope.Topic) } } return true, nil } func (w *Waku) topicInterestMatch(envelope *common.Envelope) (bool, error) { w.settingsMu.RLock() defer w.settingsMu.RUnlock() if w.settings.TopicInterest == nil { return false, nil } if !w.settings.TopicInterest[envelope.Topic] { if !w.settings.TopicInterestTolerance[envelope.Topic] { common.EnvelopesCacheFailedCounter.WithLabelValues("no_topic_interest_match").Inc() return false, fmt.Errorf("envelope does not match topic interest, hash=[%v], bloom: \n%x \n%x", envelope.Hash().Hex(), envelope.Bloom(), envelope.Topic) } } return true, nil } func (w *Waku) topicInterestOrBloomMatch(envelope *common.Envelope) (bool, error) { if w.FullNode() { return true, nil } w.settingsMu.RLock() topicInterestMode := !w.settings.BloomFilterMode w.settingsMu.RUnlock() if topicInterestMode { match, err := w.topicInterestMatch(envelope) if err != nil { return false, err } if match { return true, nil } } return w.bloomMatch(envelope) } func (w *Waku) SetBloomFilterMode(mode bool) { w.settingsMu.Lock() w.settings.BloomFilterMode = mode w.settingsMu.Unlock() // Recalculate and notify topic interest or bloom, currently not implemented } func (w *Waku) SetFullNode(set bool) { w.settingsMu.Lock() w.settings.FullNode = set w.settingsMu.Unlock() // We advertise the topic interest if full node has been disabled // or bloom filter if enabled, as that's how we indicate to a peer we are a full node or not if set { w.notifyPeersAboutBloomFilterChange(w.BloomFilter()) } else { w.notifyPeersAboutTopicInterestChange(w.TopicInterest()) } } // addEnvelope adds an envelope to the envelope map, used for sending func (w *Waku) addEnvelope(envelope *common.Envelope) { hash := envelope.Hash() w.poolMu.Lock() w.envelopes[hash] = envelope if w.expirations[envelope.Expiry] == nil { w.expirations[envelope.Expiry] = mapset.NewThreadUnsafeSet() } if !w.expirations[envelope.Expiry].Contains(hash) { w.expirations[envelope.Expiry].Add(hash) } w.poolMu.Unlock() } // addAndBridge inserts a new envelope into the message pool to be distributed within the // waku network. It also inserts the envelope into the expiration pool at the // appropriate time-stamp. In case of error, connection should be dropped. // param isP2P indicates whether the message is peer-to-peer (should not be forwarded). func (w *Waku) addAndBridge(envelope *common.Envelope, isP2P bool, bridged bool) (bool, error) { now := uint32(w.timeSource().Unix()) sent := envelope.Expiry - envelope.TTL logger := w.logger.With(zap.String("hash", envelope.Hash().String()), zap.String("site", "addAndBridge"), zap.String("topic", envelope.Topic.String()), zap.Bool("isP2P", isP2P)) logger.Debug("addAndBridge: processing envelope") common.EnvelopesReceivedCounter.Inc() if sent > now { if sent-common.DefaultSyncAllowance > now { common.EnvelopesCacheFailedCounter.WithLabelValues("in_future").Inc() logger.Warn("envelope created in the future") return false, common.TimeSyncError(errors.New("envelope from future")) } // recalculate PoW, adjusted for the time difference, plus one second for latency envelope.CalculatePoW(sent - now + 1) } if envelope.Expiry < now { if envelope.Expiry+common.DefaultSyncAllowance*2 < now { common.EnvelopesCacheFailedCounter.WithLabelValues("very_old").Inc() logger.Warn("very old envelope") return false, common.TimeSyncError(errors.New("very old envelope")) } logger.Debug("expired envelope dropped") common.EnvelopesCacheFailedCounter.WithLabelValues("expired").Inc() return false, nil // drop envelope without error } if uint32(envelope.Size()) > w.MaxMessageSize() { common.EnvelopesCacheFailedCounter.WithLabelValues("oversized").Inc() return false, fmt.Errorf("huge messages are not allowed [%s][%d][%d]", envelope.Hash().String(), envelope.Size(), w.MaxMessageSize()) } if envelope.PoW() < w.MinPow() { // maybe the value was recently changed, and the peers did not adjust yet. // in this case the previous value is retrieved by MinPowTolerance() // for a short period of peer synchronization. if envelope.PoW() < w.MinPowTolerance() { common.EnvelopesCacheFailedCounter.WithLabelValues("low_pow").Inc() return false, fmt.Errorf("envelope with low PoW received: PoW=%f, hash=[%s]", envelope.PoW(), envelope.Hash().String()) } } match, err := w.topicInterestOrBloomMatch(envelope) if err != nil { return false, err } if !match { logger.Debug("addAndBridge: no matches for envelope") return false, nil } hash := envelope.Hash() w.poolMu.Lock() _, alreadyCached := w.envelopes[hash] w.poolMu.Unlock() if !alreadyCached { logger.Debug("addAndBridge: adding envelope") w.addEnvelope(envelope) } if alreadyCached { logger.Debug("addAndBridge: already cached") common.EnvelopesCachedCounter.WithLabelValues("hit").Inc() } else { common.EnvelopesCachedCounter.WithLabelValues("miss").Inc() common.EnvelopesSizeMeter.Observe(float64(envelope.Size())) w.postEvent(envelope, isP2P) // notify the local node about the new message if w.mailServer != nil { w.mailServer.Archive(envelope) w.envelopeFeed.Send(common.EnvelopeEvent{ Topic: envelope.Topic, Hash: envelope.Hash(), Event: common.EventMailServerEnvelopeArchived, }) } // Bridge only envelopes that are not p2p messages. // In particular, if a node is a lightweight node, // it should not bridge any envelopes. if !isP2P && !bridged && w.bridge != nil { logger.Debug("bridging envelope from Waku") _, in := w.bridge.Pipe() in <- envelope common.BridgeSent.Inc() } } return true, nil } func (w *Waku) postP2P(event interface{}) { w.p2pMsgQueue <- event } // postEvent queues the message for further processing. func (w *Waku) postEvent(envelope *common.Envelope, isP2P bool) { if isP2P { w.postP2P(envelope) } else { w.msgQueue <- envelope } } // processQueue delivers the messages to the watchers during the lifetime of the waku node. func (w *Waku) processQueue() { for { select { case <-w.quit: return case e := <-w.msgQueue: w.filters.NotifyWatchers(e, false) w.envelopeFeed.Send(common.EnvelopeEvent{ Topic: e.Topic, Hash: e.Hash(), Event: common.EventEnvelopeAvailable, }) } } } func (w *Waku) processP2P() { for { select { case <-w.quit: return case e := <-w.p2pMsgQueue: switch evn := e.(type) { case *common.Envelope: // We need to insert it first, and then remove it if not matched, // as messages are processed asynchronously w.p2pMsgIDsMu.Lock() w.p2pMsgIDs[evn.Hash()] = true w.p2pMsgIDsMu.Unlock() matched := w.filters.NotifyWatchers(evn, true) // If not matched we remove it if !matched { w.p2pMsgIDsMu.Lock() delete(w.p2pMsgIDs, evn.Hash()) w.p2pMsgIDsMu.Unlock() } w.envelopeFeed.Send(common.EnvelopeEvent{ Topic: evn.Topic, Hash: evn.Hash(), Event: common.EventEnvelopeAvailable, }) case common.EnvelopeEvent: w.envelopeFeed.Send(evn) } } } } // update loops until the lifetime of the waku node, updating its internal // state by expiring stale messages from the pool. func (w *Waku) update() { // Start a ticker to check for expirations expire := time.NewTicker(common.ExpirationCycle) // Repeat updates until termination is requested for { select { case <-expire.C: w.expire() case <-w.quit: return } } } // expire iterates over all the expiration timestamps, removing all stale // messages from the pools. func (w *Waku) expire() { w.poolMu.Lock() defer w.poolMu.Unlock() logger := w.logger.With(zap.String("site", "expire")) now := uint32(w.timeSource().Unix()) for expiry, hashSet := range w.expirations { if expiry < now { // Dump all expired messages and remove timestamp hashSet.Each(func(v interface{}) bool { logger.Debug("expiring envelope", zap.String("hash", v.(gethcommon.Hash).String())) delete(w.envelopes, v.(gethcommon.Hash)) common.EnvelopesCachedCounter.WithLabelValues("clear").Inc() w.envelopeFeed.Send(common.EnvelopeEvent{ Hash: v.(gethcommon.Hash), Event: common.EventEnvelopeExpired, }) return false }) w.expirations[expiry].Clear() delete(w.expirations, expiry) } } } // Envelopes retrieves all the messages currently pooled by the node. func (w *Waku) Envelopes() []*common.Envelope { w.poolMu.RLock() defer w.poolMu.RUnlock() all := make([]*common.Envelope, 0, len(w.envelopes)) for _, envelope := range w.envelopes { all = append(all, envelope) } return all } // GetEnvelope retrieves an envelope from the message queue by its hash. // It returns nil if the envelope can not be found. func (w *Waku) GetEnvelope(hash gethcommon.Hash) *common.Envelope { w.poolMu.RLock() defer w.poolMu.RUnlock() return w.envelopes[hash] } func (w *Waku) Version() uint { return 1 } // isEnvelopeCached checks if envelope with specific hash has already been received and cached. func (w *Waku) IsEnvelopeCached(hash gethcommon.Hash) bool { w.poolMu.Lock() defer w.poolMu.Unlock() _, exist := w.envelopes[hash] return exist } func (w *Waku) ProcessingP2PMessages() bool { w.p2pMsgIDsMu.Lock() defer w.p2pMsgIDsMu.Unlock() return len(w.p2pMsgIDs) != 0 } func (w *Waku) MarkP2PMessageAsProcessed(hash gethcommon.Hash) { w.p2pMsgIDsMu.Lock() defer w.p2pMsgIDsMu.Unlock() delete(w.p2pMsgIDs, hash) } func (w *Waku) Clean() error { w.poolMu.Lock() defer w.poolMu.Unlock() w.envelopes = make(map[gethcommon.Hash]*common.Envelope) for _, f := range w.filters.All() { f.Messages = common.NewMemoryMessageStore() } return nil } // validatePrivateKey checks the format of the given private key. func validatePrivateKey(k *ecdsa.PrivateKey) bool { if k == nil || k.D == nil || k.D.Sign() == 0 { return false } return common.ValidatePublicKey(&k.PublicKey) } // makeDeterministicID generates a deterministic ID, based on a given input func makeDeterministicID(input string, keyLen int) (id string, err error) { buf := pbkdf2.Key([]byte(input), nil, 4096, keyLen, sha256.New) if !common.ValidateDataIntegrity(buf, common.KeyIDSize) { return "", fmt.Errorf("error in GenerateDeterministicID: failed to generate key") } id = gethcommon.Bytes2Hex(buf) return id, err } // toDeterministicID reviews incoming id, and transforms it to format // expected internally be private key store. Originally, public keys // were used as keys, now random keys are being used. And in order to // make it easier to consume, we now allow both random IDs and public // keys to be passed. func toDeterministicID(id string, expectedLen int) (string, error) { if len(id) != (expectedLen * 2) { // we received hex key, so number of chars in id is doubled var err error id, err = makeDeterministicID(id, expectedLen) if err != nil { return "", err } } return id, nil } func addBloom(a, b []byte) []byte { c := make([]byte, common.BloomFilterSize) for i := 0; i < common.BloomFilterSize; i++ { c[i] = a[i] | b[i] } return c }