// Copyright 2016 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 whisper import ( "crypto/ecdsa" "fmt" "sync" "github.com/ethereum/go-ethereum/common" "github.com/ethereum/go-ethereum/crypto" "github.com/ethereum/go-ethereum/log" ) // MessageStore defines interface for temporary message store. type MessageStore interface { Add(*ReceivedMessage) error Pop() ([]*ReceivedMessage, error) } // NewMemoryMessageStore returns pointer to an instance of the MemoryMessageStore. func NewMemoryMessageStore() *MemoryMessageStore { return &MemoryMessageStore{ messages: map[common.Hash]*ReceivedMessage{}, } } // MemoryMessageStore stores massages in memory hash table. type MemoryMessageStore struct { mu sync.Mutex messages map[common.Hash]*ReceivedMessage } // Add adds message to store. func (store *MemoryMessageStore) Add(msg *ReceivedMessage) error { store.mu.Lock() defer store.mu.Unlock() if _, exist := store.messages[msg.EnvelopeHash]; !exist { store.messages[msg.EnvelopeHash] = msg } return nil } // Pop returns all available messages and cleans the store. func (store *MemoryMessageStore) Pop() ([]*ReceivedMessage, error) { store.mu.Lock() defer store.mu.Unlock() all := make([]*ReceivedMessage, 0, len(store.messages)) for hash, msg := range store.messages { delete(store.messages, hash) all = append(all, msg) } return all, nil } // Filter represents a Whisper message filter type Filter struct { Src *ecdsa.PublicKey // Sender of the message KeyAsym *ecdsa.PrivateKey // Private Key of recipient KeySym []byte // Key associated with the Topic Topics [][]byte // Topics to filter messages with PoW float64 // Proof of work as described in the Whisper spec AllowP2P bool // Indicates whether this filter is interested in direct peer-to-peer messages SymKeyHash common.Hash // The Keccak256Hash of the symmetric key, needed for optimization id string // unique identifier Messages MessageStore } // Filters represents a collection of filters type Filters struct { watchers map[string]*Filter topicMatcher map[TopicType]map[*Filter]struct{} // map a topic to the filters that are interested in being notified when a message matches that topic allTopicsMatcher map[*Filter]struct{} // list all the filters that will be notified of a new message, no matter what its topic is whisper *Whisper mutex sync.RWMutex } // NewFilters returns a newly created filter collection func NewFilters(w *Whisper) *Filters { return &Filters{ watchers: make(map[string]*Filter), topicMatcher: make(map[TopicType]map[*Filter]struct{}), allTopicsMatcher: make(map[*Filter]struct{}), whisper: w, } } // Install will add a new filter to the filter collection func (fs *Filters) Install(watcher *Filter) (string, error) { if watcher.KeySym != nil && watcher.KeyAsym != nil { return "", fmt.Errorf("filters must choose between symmetric and asymmetric keys") } id, err := GenerateRandomID() if err != nil { return "", err } fs.mutex.Lock() defer fs.mutex.Unlock() if fs.watchers[id] != nil { return "", fmt.Errorf("failed to generate unique ID") } if watcher.expectsSymmetricEncryption() { watcher.SymKeyHash = crypto.Keccak256Hash(watcher.KeySym) } watcher.id = id fs.watchers[id] = watcher fs.addTopicMatcher(watcher) return id, err } // Uninstall will remove a filter whose id has been specified from // the filter collection func (fs *Filters) Uninstall(id string) bool { fs.mutex.Lock() defer fs.mutex.Unlock() if fs.watchers[id] != nil { fs.removeFromTopicMatchers(fs.watchers[id]) delete(fs.watchers, id) return true } return false } // addTopicMatcher adds a filter to the topic matchers. // If the filter's Topics array is empty, it will be tried on every topic. // Otherwise, it will be tried on the topics specified. func (fs *Filters) addTopicMatcher(watcher *Filter) { if len(watcher.Topics) == 0 { fs.allTopicsMatcher[watcher] = struct{}{} } else { for _, t := range watcher.Topics { topic := BytesToTopic(t) if fs.topicMatcher[topic] == nil { fs.topicMatcher[topic] = make(map[*Filter]struct{}) } fs.topicMatcher[topic][watcher] = struct{}{} } } } // removeFromTopicMatchers removes a filter from the topic matchers func (fs *Filters) removeFromTopicMatchers(watcher *Filter) { delete(fs.allTopicsMatcher, watcher) for _, topic := range watcher.Topics { delete(fs.topicMatcher[BytesToTopic(topic)], watcher) } } // getWatchersByTopic returns a slice containing the filters that // match a specific topic func (fs *Filters) getWatchersByTopic(topic TopicType) []*Filter { res := make([]*Filter, 0, len(fs.allTopicsMatcher)) for watcher := range fs.allTopicsMatcher { res = append(res, watcher) } for watcher := range fs.topicMatcher[topic] { res = append(res, watcher) } return res } // Get returns a filter from the collection with a specific ID func (fs *Filters) Get(id string) *Filter { fs.mutex.RLock() defer fs.mutex.RUnlock() return fs.watchers[id] } // NotifyWatchers notifies any filter that has declared interest // for the envelope's topic. func (fs *Filters) NotifyWatchers(env *Envelope, p2pMessage bool) { var msg *ReceivedMessage fs.mutex.RLock() defer fs.mutex.RUnlock() candidates := fs.getWatchersByTopic(env.Topic) for _, watcher := range candidates { if p2pMessage && !watcher.AllowP2P { log.Trace(fmt.Sprintf("msg [%x], filter [%s]: p2p messages are not allowed", env.Hash(), watcher.id)) continue } var match bool if msg != nil { match = watcher.MatchMessage(msg) } else { match = watcher.MatchEnvelope(env) if match { msg = env.Open(watcher) if msg == nil { log.Trace("processing message: failed to open", "message", env.Hash().Hex(), "filter", watcher.id) } } else { log.Trace("processing message: does not match", "message", env.Hash().Hex(), "filter", watcher.id) } } if match && msg != nil { msg.P2P = p2pMessage log.Trace("processing message: decrypted", "hash", env.Hash().Hex()) if watcher.Src == nil || IsPubKeyEqual(msg.Src, watcher.Src) { watcher.Trigger(msg) } } } } func (f *Filter) expectsAsymmetricEncryption() bool { return f.KeyAsym != nil } func (f *Filter) expectsSymmetricEncryption() bool { return f.KeySym != nil } // Trigger adds a yet-unknown message to the filter's list of // received messages. func (f *Filter) Trigger(msg *ReceivedMessage) { err := f.Messages.Add(msg) if err != nil { log.Error("failed to add msg into the filters store", "hash", msg.EnvelopeHash, "error", err) } } // Retrieve will return the list of all received messages associated // to a filter. func (f *Filter) Retrieve() []*ReceivedMessage { msgs, err := f.Messages.Pop() if err != nil { log.Error("failed to retrieve messages from filter store", "error", err) return nil } return msgs } // MatchMessage checks if the filter matches an already decrypted // message (i.e. a Message that has already been handled by // MatchEnvelope when checked by a previous filter). // Topics are not checked here, since this is done by topic matchers. func (f *Filter) MatchMessage(msg *ReceivedMessage) bool { if f.PoW > 0 && msg.PoW < f.PoW { return false } if f.expectsAsymmetricEncryption() && msg.isAsymmetricEncryption() { return IsPubKeyEqual(&f.KeyAsym.PublicKey, msg.Dst) } else if f.expectsSymmetricEncryption() && msg.isSymmetricEncryption() { return f.SymKeyHash == msg.SymKeyHash } return false } // MatchEnvelope checks if it's worth decrypting the message. If // it returns `true`, client code is expected to attempt decrypting // the message and subsequently call MatchMessage. // Topics are not checked here, since this is done by topic matchers. func (f *Filter) MatchEnvelope(envelope *Envelope) bool { return f.PoW <= 0 || envelope.pow >= f.PoW } // IsPubKeyEqual checks that two public keys are equal func IsPubKeyEqual(a, b *ecdsa.PublicKey) bool { if !ValidatePublicKey(a) { return false } else if !ValidatePublicKey(b) { return false } // the curve is always the same, just compare the points return a.X.Cmp(b.X) == 0 && a.Y.Cmp(b.Y) == 0 }