// Copyright (c) 2013 Conformal Systems LLC. // Use of this source code is governed by an ISC // license that can be found in the LICENSE file. package main import ( "bytes" "container/list" crand "crypto/rand" // for seeding "encoding/binary" "encoding/json" "fmt" "github.com/conformal/btcwire" "io" "math" "math/rand" "net" "os" "path/filepath" "strconv" "sync" "time" ) const ( // maxAddresses identifies the maximum number of addresses that the // address manager will track. maxAddresses = 2500 // needAddressThreshold is the number of addresses under which the // address manager will claim to need more addresses. needAddressThreshold = 1000 newAddressBufferSize = 50 // dumpAddressInterval is the interval used to dump the address // cache to disk for future use. dumpAddressInterval = time.Minute * 2 // triedBucketSize is the maximum number of addresses in each // tried address bucket. triedBucketSize = 64 // triedBucketCount is the number of buckets we split tried // addresses over. triedBucketCount = 64 // newBucketSize is the maximum number of addresses in each new address // bucket. newBucketSize = 64 // newBucketCount is the number of buckets taht we spread new addresses // over. newBucketCount = 256 // triedBucketsPerGroup is the number of trieed buckets over which an // address group will be spread. triedBucketsPerGroup = 4 // newBucketsPerGroup is the number of new buckets over which an // source address group will be spread. newBucketsPerGroup = 32 // newBucketsPerAddress is the number of buckets a frequently seen new // address may end up in. newBucketsPerAddress = 4 // numMissingDays is the number of days before which we assume an // address has vanished if we have not seen it announced in that long. numMissingDays = 30 // numRetries is the number of tried without a single success before // we assume an address is bad. numRetries = 3 // maxFailures is the maximum number of failures we will accept without // a success before considering an address bad. maxFailures = 10 // minBadDays is the number of days since the last success before we // will consider evicting an address. minBadDays = 7 // getAddrMax is the most addresses that we will send in response // to a getAddr (in practise the most addresses we will return from a // call to AddressCache()). getAddrMax = 2500 // getAddrPercent is the percentage of total addresses known that we // will share with a call to AddressCache. getAddrPercent = 23 // serialisationVersion is the current version of the on-disk format. serialisationVersion = 1 ) // updateAddress is a helper function to either update an address already known // to the address manager, or to add the address if not already known. func (a *AddrManager) updateAddress(netAddr, srcAddr *btcwire.NetAddress) { // Filter out non-routable addresses. Note that non-routable // also includes invalid and local addresses. if !Routable(netAddr) { return } // Protect concurrent access. a.mtx.Lock() defer a.mtx.Unlock() addr := NetAddressKey(netAddr) ka := a.find(netAddr) if ka != nil { // TODO(oga) only update adresses periodically. // Update the last seen time. if netAddr.Timestamp.After(ka.na.Timestamp) { ka.na.Timestamp = netAddr.Timestamp } // Update services. ka.na.AddService(netAddr.Services) // If already in tried, we have nothing to do here. if ka.tried { return } // Already at our max? if ka.refs == newBucketsPerAddress { return } // The more entries we have, the less likely we are to add more. // likelyhood is 2N. factor := int32(2 * ka.refs) if a.rand.Int31n(factor) != 0 { return } } else { ka = &knownAddress{na: netAddr, srcAddr: srcAddr} a.addrIndex[addr] = ka a.nNew++ // XXX time penalty? } bucket := a.getNewBucket(netAddr, srcAddr) // Already exists? if _, ok := a.addrNew[bucket][addr]; ok { return } // Enforce max addresses. if len(a.addrNew[bucket]) > newBucketSize { log.Tracef("[AMGR] new bucket is full, expiring old ") a.expireNew(bucket) } // Add to new bucket. ka.refs++ a.addrNew[bucket][addr] = ka log.Tracef("[AMGR] Added new address %s for a total of %d addresses", addr, a.nTried+a.nNew) } // bad returns true if the address in question has not been tried in the last // minute and meets one of the following criteria: // 1) It claims to be from the future // 2) It hasn't been seen in over a month // 3) It has failed at least three times and never succeeded // 4) It has failed ten times in the last week // All addresses that meet these criteria are assumed to be worthless and not // worth keeping hold of. func bad(ka *knownAddress) bool { if ka.lastattempt.After(time.Now().Add(-1 * time.Minute)) { return false } // From the future? if ka.na.Timestamp.After(time.Now().Add(10 * time.Minute)) { return true } // Over a month old? if ka.na.Timestamp.After(time.Now().Add(-1 * numMissingDays * time.Hour * 24)) { return true } // Never succeeded? if ka.lastsuccess.IsZero() && ka.attempts >= numRetries { return true } // Hasn't succeeded in too long? if !ka.lastsuccess.After(time.Now().Add(-1*minBadDays*time.Hour*24)) && ka.attempts >= maxFailures { return true } return false } // chance returns the selection probability for a known address. The priority // depends upon how recent the address has been seen, how recent it was last // attempted and how often attempts to connect to it have failed. func chance(ka *knownAddress) float64 { c := 1.0 now := time.Now() var lastSeen float64 var lastTry float64 if !ka.na.Timestamp.After(now) { var dur time.Duration if ka.na.Timestamp.IsZero() { // use unix epoch to match bitcoind. dur = now.Sub(time.Unix(0, 0)) } else { dur = now.Sub(ka.na.Timestamp) } lastSeen = dur.Seconds() } if !ka.lastattempt.After(now) { var dur time.Duration if ka.lastattempt.IsZero() { // use unix epoch to match bitcoind. dur = now.Sub(time.Unix(0, 0)) } else { dur = now.Sub(ka.lastattempt) } lastTry = dur.Seconds() } c = 600.0 / (600.0 + lastSeen) // Very recent attempts are less likely to be retried. if lastTry > 60.0*10.0 { c *= 0.01 } // Failed attempts deprioritise. if ka.attempts > 0 { c /= float64(ka.attempts) * 1.5 } return c } // expireNew makes space in the new buckets by expiring the really bad entries. // If no bad entries are available we look at a few and remove the oldest. func (a *AddrManager) expireNew(bucket int) { // First see if there are any entries that are so bad we can just throw // them away. otherwise we throw away the oldest entry in the cache. // Bitcoind here chooses four random and just throws the oldest of // those away, but we keep track of oldest in the initial traversal and // use that information instead. var oldest *knownAddress for k, v := range a.addrNew[bucket] { if bad(v) { log.Tracef("[AMGR] expiring bad address %v", k) delete(a.addrNew[bucket], k) a.nNew-- v.refs-- if v.refs == 0 { delete(a.addrIndex, k) } return } if oldest == nil { oldest = v } else if !v.na.Timestamp.After(oldest.na.Timestamp) { oldest = v } } if oldest != nil { key := NetAddressKey(oldest.na) log.Tracef("[AMGR] expiring oldest address %v", key) delete(a.addrNew[bucket], key) a.nNew-- oldest.refs-- if oldest.refs == 0 { delete(a.addrIndex, key) } } } // pickTried selects an address from the tried bucket to be evicted. // We just choose the eldest. Bitcoind selects 4 random entries and throws away // the older of them. func (a *AddrManager) pickTried(bucket int) *list.Element { var oldest *knownAddress var oldestElem *list.Element for e := a.addrTried[bucket].Front(); e != nil; e = e.Next() { ka := e.Value.(*knownAddress) if oldest == nil || oldest.na.Timestamp.After(ka.na.Timestamp) { oldestElem = e oldest = ka } } return oldestElem } // knownAddress tracks information about a known network address that is used // to determine how viable an address is. type knownAddress struct { na *btcwire.NetAddress srcAddr *btcwire.NetAddress attempts int lastattempt time.Time lastsuccess time.Time tried bool refs int // reference count of new buckets } // AddrManager provides a concurrency safe address manager for caching potential // peers on the bitcoin network. type AddrManager struct { mtx sync.Mutex rand *rand.Rand key [32]byte addrIndex map[string]*knownAddress // address key to ka for all addrs. addrNew [newBucketCount]map[string]*knownAddress addrTried [triedBucketCount]*list.List started bool shutdown bool wg sync.WaitGroup quit chan bool nTried int nNew int } func (a *AddrManager) getNewBucket(netAddr, srcAddr *btcwire.NetAddress) int { // bitcoind: // doublesha256(key + sourcegroup + int64(doublesha256(key + group + sourcegroup))%bucket_per_source_group) % num_new_buckes data1 := []byte{} data1 = append(data1, a.key[:]...) data1 = append(data1, []byte(GroupKey(netAddr))...) data1 = append(data1, []byte(GroupKey(srcAddr))...) hash1 := btcwire.DoubleSha256(data1) hash64 := binary.LittleEndian.Uint64(hash1) hash64 %= newBucketsPerGroup hashbuf := new(bytes.Buffer) binary.Write(hashbuf, binary.LittleEndian, hash64) data2 := []byte{} data2 = append(data2, a.key[:]...) data2 = append(data2, GroupKey(srcAddr)...) data2 = append(data2, hashbuf.Bytes()...) hash2 := btcwire.DoubleSha256(data2) return int(binary.LittleEndian.Uint64(hash2) % newBucketCount) } func (a *AddrManager) getTriedBucket(netAddr *btcwire.NetAddress) int { // bitcoind hashes this as: // doublesha256(key + group + truncate_to_64bits(doublesha256(key)) % buckets_per_group) % num_buckets data1 := []byte{} data1 = append(data1, a.key[:]...) data1 = append(data1, []byte(NetAddressKey(netAddr))...) hash1 := btcwire.DoubleSha256(data1) hash64 := binary.LittleEndian.Uint64(hash1) hash64 %= triedBucketsPerGroup hashbuf := new(bytes.Buffer) binary.Write(hashbuf, binary.LittleEndian, hash64) data2 := []byte{} data2 = append(data2, a.key[:]...) data2 = append(data2, GroupKey(netAddr)...) data2 = append(data2, hashbuf.Bytes()...) hash2 := btcwire.DoubleSha256(data2) return int(binary.LittleEndian.Uint64(hash2) % triedBucketCount) } // addressHandler is the main handler for the address manager. It must be run // as a goroutine. func (a *AddrManager) addressHandler() { dumpAddressTicker := time.NewTicker(dumpAddressInterval) out: for !a.shutdown { select { case <-dumpAddressTicker.C: if !a.shutdown { a.savePeers() } case <-a.quit: a.savePeers() break out } } dumpAddressTicker.Stop() a.wg.Done() log.Trace("[AMGR] Address handler done") } type serialisedKnownAddress struct { Addr string Src string Attempts int TimeStamp int64 LastAttempt int64 LastSuccess int64 // no refcount or tried, that is available from context. } type serialisedAddrManager struct { Version int Key [32]byte Addresses []*serialisedKnownAddress NewBuckets [newBucketCount][]string // string is NetAddressKey TriedBuckets [triedBucketCount][]string } // savePeers saves all the known addresses to a file so they can be read back // in at next run. func (a *AddrManager) savePeers() { a.mtx.Lock() defer a.mtx.Unlock() // First we make a serialisable datastructure so we can encode it to // json. sam := new(serialisedAddrManager) sam.Version = serialisationVersion copy(sam.Key[:], a.key[:]) sam.Addresses = make([]*serialisedKnownAddress, len(a.addrIndex)) i := 0 for k, v := range a.addrIndex { ska := new(serialisedKnownAddress) ska.Addr = k ska.TimeStamp = v.na.Timestamp.Unix() ska.Src = NetAddressKey(v.srcAddr) ska.Attempts = v.attempts ska.LastAttempt = v.lastattempt.Unix() ska.LastSuccess = v.lastsuccess.Unix() // Tried and refs are implicit in the rest of the structure // and will be worked out from context on unserialisation. sam.Addresses[i] = ska i++ } for i := range a.addrNew { sam.NewBuckets[i] = make([]string, len(a.addrNew[i])) j := 0 for k := range a.addrNew[i] { sam.NewBuckets[i][j] = k j++ } } for i := range a.addrTried { sam.TriedBuckets[i] = make([]string, a.addrTried[i].Len()) j := 0 for e := a.addrTried[i].Front(); e != nil; e = e.Next() { ka := e.Value.(*knownAddress) sam.TriedBuckets[i][j] = NetAddressKey(ka.na) j++ } } // May give some way to specify this later. filename := "peers.json" filePath := filepath.Join(cfg.DataDir, filename) w, err := os.Create(filePath) if err != nil { log.Error("Error opening file: ", filePath, err) } enc := json.NewEncoder(w) defer w.Close() enc.Encode(&sam) } // loadPeers loads the known address from the saved file. If empty, missing, or // malformed file, just don't load anything and start fresh func (a *AddrManager) loadPeers() { a.mtx.Lock() defer a.mtx.Unlock() // May give some way to specify this later. filename := "peers.json" filePath := filepath.Join(cfg.DataDir, filename) err := a.deserialisePeers(filePath) if err != nil { log.Errorf("[AMGR] Failed to parse %s: %v", filePath, err) // if it is invalid we nuke the old one unconditionally. err = os.Remove(filePath) if err != nil { log.Warn("Failed to remove corrupt peers "+ "file: ", err) } a.reset() return } log.Infof("[AMGR] Successfuly loaded %d addresses from %s", a.nNew+a.nTried, filePath) } func (a *AddrManager) deserialisePeers(filePath string) error { _, err := os.Stat(filePath) if os.IsNotExist(err) { return nil } r, err := os.Open(filePath) if err != nil { return fmt.Errorf("%s error opening file: ", filePath, err) } defer r.Close() var sam serialisedAddrManager dec := json.NewDecoder(r) err = dec.Decode(&sam) if err != nil { return fmt.Errorf("error reading %s: %v", filePath, err) } if sam.Version != serialisationVersion { return fmt.Errorf("unknown version %v in serialised "+ "addrmanager", sam.Version) } copy(a.key[:], sam.Key[:]) for _, v := range sam.Addresses { ka := new(knownAddress) ka.na, err = deserialiseNetAddress(v.Addr) if err != nil { return fmt.Errorf("failed to deserialise netaddress "+ "%s: %v", v.Addr, err) } ka.srcAddr, err = deserialiseNetAddress(v.Src) if err != nil { return fmt.Errorf("failed to deserialise netaddress "+ "%s: %v", v.Src, err) } ka.attempts = v.Attempts ka.lastattempt = time.Unix(v.LastAttempt, 0) ka.lastsuccess = time.Unix(v.LastSuccess, 0) a.addrIndex[NetAddressKey(ka.na)] = ka } for i := range sam.NewBuckets { for _, val := range sam.NewBuckets[i] { ka, ok := a.addrIndex[val] if !ok { return fmt.Errorf("newbucket contains %s but "+ "none in address list", val) } if ka.refs == 0 { a.nNew++ } ka.refs++ a.addrNew[i][val] = ka } } for i := range sam.TriedBuckets { for _, val := range sam.TriedBuckets[i] { ka, ok := a.addrIndex[val] if !ok { return fmt.Errorf("Newbucket contains %s but "+ "none in address list", val) } ka.tried = true a.nTried++ a.addrTried[i].PushBack(ka) } } // Sanity checking. for k, v := range a.addrIndex { if v.refs == 0 && !v.tried { return fmt.Errorf("address %s after serialisation "+ "with no references", k) } if v.refs > 0 && v.tried { return fmt.Errorf("address %s after serialisation "+ "which is both new and tried!", k) } } return nil } func deserialiseNetAddress(addr string) (*btcwire.NetAddress, error) { host, portStr, err := net.SplitHostPort(addr) if err != nil { return nil, err } ip := net.ParseIP(host) port, err := strconv.ParseUint(portStr, 10, 16) if err != nil { return nil, err } na := btcwire.NewNetAddressIPPort(ip, uint16(port), btcwire.SFNodeNetwork) return na, nil } // Start begins the core address handler which manages a pool of known // addresses, timeouts, and interval based writes. func (a *AddrManager) Start() { // Already started? if a.started { return } log.Trace("[AMGR] Starting address manager") a.wg.Add(1) go a.addressHandler() a.started = true // Load peers we already know about from file. a.loadPeers() } // Stop gracefully shuts down the address manager by stopping the main handler. func (a *AddrManager) Stop() error { if a.shutdown { log.Warnf("[AMGR] Address manager is already in the process of " + "shutting down") return nil } log.Infof("[AMGR] Address manager shutting down") a.savePeers() a.shutdown = true a.quit <- true a.wg.Wait() return nil } // AddAddresses adds new addresses to the address manager. It enforces a max // number of addresses and silently ignores duplicate addresses. It is // safe for concurrent access. func (a *AddrManager) AddAddresses(addrs []*btcwire.NetAddress, srcAddr *btcwire.NetAddress) { for _, na := range addrs { a.updateAddress(na, srcAddr) } } // AddAddress adds a new address to the address manager. It enforces a max // number of addresses and silently ignores duplicate addresses. It is // safe for concurrent access. func (a *AddrManager) AddAddress(addr *btcwire.NetAddress, srcAddr *btcwire.NetAddress) { a.AddAddresses([]*btcwire.NetAddress{addr}, srcAddr) } // AddAddressByIP adds an address where we are given an ip:port and not a // btcwire.NetAddress. func (a *AddrManager) AddAddressByIP(addrIP string) { // Split IP and port addr, portStr, err := net.SplitHostPort(addrIP) if err != nil { log.Warnf("[AMGR] AddADddressByIP given bullshit adddress"+ "(%s): %v", err) return } // Put it in btcwire.Netaddress var na btcwire.NetAddress na.Timestamp = time.Now() na.IP = net.ParseIP(addr) if na.IP == nil { log.Error("[AMGR] Invalid ip address:", addr) return } port, err := strconv.ParseUint(portStr, 10, 0) if err != nil { log.Error("[AMGR] Invalid port: ", portStr, err) return } na.Port = uint16(port) a.AddAddress(&na, &na) // XXX use correct src address } // NeedMoreAddresses returns whether or not the address manager needs more // addresses. func (a *AddrManager) NeedMoreAddresses() bool { // NumAddresses handles concurrent access for us. return a.NumAddresses() < needAddressThreshold } // NumAddresses returns the number of addresses known to the address manager. func (a *AddrManager) NumAddresses() int { a.mtx.Lock() defer a.mtx.Unlock() return a.nTried + a.nNew } // AddressCache returns the current address cache. It must be treated as // read-only (but since it is a copy now, this is not as dangerous). func (a *AddrManager) AddressCache() []*btcwire.NetAddress { a.mtx.Lock() defer a.mtx.Unlock() if a.nNew+a.nTried == 0 { return nil } allAddr := make([]*btcwire.NetAddress, a.nNew+a.nTried) i := 0 // Iteration order is undefined here, but we randomise it anyway. for _, v := range a.addrIndex { allAddr[i] = v.na i++ } // Fisher-Yates shuffle the array for i := range allAddr { j := rand.Intn(i + 1) allAddr[i], allAddr[j] = allAddr[j], allAddr[i] } numAddresses := len(allAddr) * getAddrPercent / 100 if numAddresses > getAddrMax { numAddresses = getAddrMax } // slice off the limit we are willing to share. return allAddr[:numAddresses] } // reset resets the address manager by reinitialising the random source // and allocating fresh empty bucket storage. func (a *AddrManager) reset() { a.addrIndex = make(map[string]*knownAddress) // fill key with bytes from a good random source. io.ReadFull(crand.Reader, a.key[:]) for i := range a.addrNew { a.addrNew[i] = make(map[string]*knownAddress) } for i := range a.addrTried { a.addrTried[i] = list.New() } } // New returns a new bitcoin address manager. // Use Start to begin processing asynchronous address updates. func NewAddrManager() *AddrManager { am := AddrManager{ rand: rand.New(rand.NewSource(time.Now().UnixNano())), quit: make(chan bool), } am.reset() return &am } // NetAddressKey returns a string key in the form of ip:port for IPv4 addresses // or [ip]:port for IPv6 addresses. func NetAddressKey(na *btcwire.NetAddress) string { port := strconv.FormatUint(uint64(na.Port), 10) addr := net.JoinHostPort(na.IP.String(), port) return addr } // GetAddress returns a single address that should be routable. It picks a // random one from the possible addresses with preference given to ones that // have not been used recently and should not pick 'close' addresses // consecutively. func (a *AddrManager) GetAddress(class string, newBias int) *knownAddress { if a.NumAddresses() == 0 { return nil } // Protect concurrent access. a.mtx.Lock() defer a.mtx.Unlock() if newBias > 100 { newBias = 100 } if newBias < 0 { newBias = 0 } // Bias between new and tried addresses. triedCorrelation := math.Sqrt(float64(a.nTried)) * (100.0 - float64(newBias)) newCorrelation := math.Sqrt(float64(a.nNew)) * float64(newBias) if (newCorrelation+triedCorrelation)*a.rand.Float64() < triedCorrelation { // Tried entry. large := 1 << 30 factor := 1.0 for { // pick a random bucket. bucket := a.rand.Intn(len(a.addrTried)) if a.addrTried[bucket].Len() == 0 { continue } // Pick a random entry in the list e := a.addrTried[bucket].Front() for i := a.rand.Int63n(int64(a.addrTried[bucket].Len())); i > 0; i-- { e = e.Next() } ka := e.Value.(*knownAddress) randval := a.rand.Intn(large) if float64(randval) < (factor * chance(ka) * float64(large)) { log.Tracef("[AMGR] Selected %v from tried "+ "bucket", NetAddressKey(ka.na)) return ka } factor *= 1.2 } } else { // new node. // XXX use a closure/function to avoid repeating this. large := 1 << 30 factor := 1.0 for { // Pick a random bucket. bucket := a.rand.Intn(len(a.addrNew)) if len(a.addrNew[bucket]) == 0 { continue } // Then, a random entry in it. var ka *knownAddress nth := a.rand.Intn(len(a.addrNew[bucket])) for _, value := range a.addrNew[bucket] { if nth == 0 { ka = value } nth-- } randval := a.rand.Intn(large) if float64(randval) < (factor * chance(ka) * float64(large)) { log.Tracef("[AMGR] Selected %v from new bucket", NetAddressKey(ka.na)) return ka } factor *= 1.2 } } } func (a *AddrManager) find(addr *btcwire.NetAddress) *knownAddress { return a.addrIndex[NetAddressKey(addr)] } /* * Connected - updates the last seen time but only every 20 minutes. * Good - last tried = last success = last seen = now. attmempts = 0. * - move address to tried. * Attempted - set last tried to time. nattempts++ */ func (a *AddrManager) Attempt(addr *btcwire.NetAddress) { a.mtx.Lock() defer a.mtx.Unlock() // find address. // Surely address will be in tried by now? ka := a.find(addr) if ka == nil { return } // set last tried time to now ka.attempts++ ka.lastattempt = time.Now() } // Connected Marks the given address as currently connected and working at the // current time. The address must already be known to AddrManager else it will // be ignored. func (a *AddrManager) Connected(addr *btcwire.NetAddress) { a.mtx.Lock() defer a.mtx.Unlock() ka := a.find(addr) if ka == nil { return } // Update the time as long as it has been 20 minutes since last we did // so. now := time.Now() if now.After(ka.na.Timestamp.Add(time.Minute * 20)) { ka.na.Timestamp = time.Now() } } // Good marks the given address as good. To be called after a successful // connection and version exchange. If the address is unknown to the addresss // manager it will be ignored. func (a *AddrManager) Good(addr *btcwire.NetAddress) { a.mtx.Lock() defer a.mtx.Unlock() ka := a.find(addr) if ka == nil { return } now := time.Now() ka.lastsuccess = now ka.lastattempt = now ka.na.Timestamp = now ka.attempts = 0 // move to tried set, optionally evicting other addresses if neeed. if ka.tried { return } // ok, need to move it to tried. // remove from all new buckets. // record one of the buckets in question and call it the `first' addrKey := NetAddressKey(addr) oldBucket := -1 for i := range a.addrNew { // we check for existance so we can record the first one if _, ok := a.addrNew[i][addrKey]; ok { delete(a.addrNew[i], addrKey) ka.refs-- if oldBucket == -1 { oldBucket = i } } } a.nNew-- if oldBucket == -1 { // What? wasn't in a bucket after all.... Panic? return } bucket := a.getTriedBucket(ka.na) // Room in this tried bucket? if a.addrTried[bucket].Len() < triedBucketSize { ka.tried = true a.addrTried[bucket].PushBack(ka) a.nTried++ return } // No room, we have to evict something else. entry := a.pickTried(bucket) rmka := entry.Value.(*knownAddress) // First bucket it would have been put in. newBucket := a.getNewBucket(rmka.na, rmka.srcAddr) // If no room in the original bucket, we put it in a bucket we just // freed up a space in. if len(a.addrNew[newBucket]) >= newBucketSize { newBucket = oldBucket } // replace with ka in list. ka.tried = true entry.Value = ka rmka.tried = false rmka.refs++ // We don't touch a.nTried here since the number of tried stays the same // but we decemented new above, raise it again since we're putting // something back. a.nNew++ rmkey := NetAddressKey(rmka.na) log.Tracef("[AMGR] replacing %s with %s in tried", rmkey, addrKey) // We made sure there is space here just above. a.addrNew[newBucket][rmkey] = rmka } // RFC1918: IPv4 Private networks (10.0.0.0/8, 192.168.0.0/16, 172.16.0.0/12) var rfc1918ten = net.IPNet{IP: net.ParseIP("10.0.0.0"), Mask: net.CIDRMask(8, 32)} var rfc1918oneninetwo = net.IPNet{IP: net.ParseIP("192.168.0.0"), Mask: net.CIDRMask(16, 32)} var rfc1918oneseventwo = net.IPNet{IP: net.ParseIP("172.16.0.0"), Mask: net.CIDRMask(12, 32)} func RFC1918(na *btcwire.NetAddress) bool { return rfc1918ten.Contains(na.IP) || rfc1918oneninetwo.Contains(na.IP) || rfc1918oneseventwo.Contains(na.IP) } // RFC3849 IPv6 Documentation address (2001:0DB8::/32) var rfc3849 = net.IPNet{IP: net.ParseIP("2001:0DB8::"), Mask: net.CIDRMask(32, 128)} func RFC3849(na *btcwire.NetAddress) bool { return rfc3849.Contains(na.IP) } // RFC3927 IPv4 Autoconfig (169.254.0.0/16) var rfc3927 = net.IPNet{IP: net.ParseIP("169.254.0.0"), Mask: net.CIDRMask(16, 32)} func RFC3927(na *btcwire.NetAddress) bool { return rfc3927.Contains(na.IP) } // RFC3964 IPv6 6to4 (2002::/16) var rfc3964 = net.IPNet{IP: net.ParseIP("2002::"), Mask: net.CIDRMask(16, 128)} func RFC3964(na *btcwire.NetAddress) bool { return rfc3964.Contains(na.IP) } // RFC4193 IPv6 unique local (FC00::/7) var rfc4193 = net.IPNet{IP: net.ParseIP("FC00::"), Mask: net.CIDRMask(7, 128)} func RFC4193(na *btcwire.NetAddress) bool { return rfc4193.Contains(na.IP) } // RFC4380 IPv6 Teredo tunneling (2001::/32) var rfc4380 = net.IPNet{IP: net.ParseIP("2001::"), Mask: net.CIDRMask(32, 128)} func RFC4380(na *btcwire.NetAddress) bool { return rfc4380.Contains(na.IP) } // RFC4843 IPv6 ORCHID: (2001:10::/28) var rfc4843 = net.IPNet{IP: net.ParseIP("2001:10::"), Mask: net.CIDRMask(28, 128)} func RFC4843(na *btcwire.NetAddress) bool { return rfc4843.Contains(na.IP) } // RFC4862 IPv6 Autoconfig (FE80::/64) var rfc4862 = net.IPNet{IP: net.ParseIP("FE80::"), Mask: net.CIDRMask(64, 128)} func RFC4862(na *btcwire.NetAddress) bool { return rfc4862.Contains(na.IP) } // RFC6052: IPv6 well known prefix (64:FF9B::/96) var rfc6052 = net.IPNet{IP: net.ParseIP("64:FF9B::"), Mask: net.CIDRMask(96, 128)} func RFC6052(na *btcwire.NetAddress) bool { return rfc6052.Contains(na.IP) } // RFC6145: IPv6 IPv4 translated address ::FFFF:0:0:0/96 var rfc6145 = net.IPNet{IP: net.ParseIP("::FFFF:0:0:0"), Mask: net.CIDRMask(96, 128)} func RFC6145(na *btcwire.NetAddress) bool { return rfc6145.Contains(na.IP) } func Tor(na *btcwire.NetAddress) bool { // bitcoind encodes a .onion address as a 16 byte number by decoding the // address prior to the .onion (i.e. the key hash) base32 into a ten // byte number. it then stores the first 6 bytes of the address as // 0xfD, 0x87, 0xD8, 0x7e, 0xeb, 0x43 // making the format // { magic 6 bytes, 10 bytes base32 decode of key hash } // Since we use btcwire.NetAddress to represent and address we may // well have to emulate this. // XXX fillmein return false } var zero4 = net.IPNet{IP: net.ParseIP("0.0.0.0"), Mask: net.CIDRMask(8, 32)} func Local(na *btcwire.NetAddress) bool { return na.IP.IsLoopback() || zero4.Contains(na.IP) } // Valid returns true if an address is not one of the invalid formats. // For IPv4 these are either a 0 or all bits set address. For IPv6 a zero // address or one that matches the RFC3849 documentation address format. func Valid(na *btcwire.NetAddress) bool { // IsUnspecified returns if address is 0, so only all bits set, and // RFC3849 need to be explicitly checked. bitcoind here also checks for // invalid protocol addresses from earlier versions of bitcoind (before // 0.2.9), however, since protocol versions before 70001 are // disconnected by the bitcoin network now we have elided it. return !(na.IP.IsUnspecified() || RFC3849(na) || na.IP.Equal(net.IPv4bcast)) } // Routable returns whether a netaddress is routable on the public internet or // not. This is true as long as the address is valid and is not in any reserved // ranges. func Routable(na *btcwire.NetAddress) bool { return Valid(na) && !(RFC1918(na) || RFC3927(na) || RFC4862(na) || RFC4193(na) || Tor(na) || RFC4843(na) || Local(na)) } // GroupKey returns a string representing the network group an address // is part of. // This is the /16 for IPv6, the /32 (/36 for he.net) for IPv6, the string // "local" for a local address and the string "unroutable for an unroutable // address. func GroupKey(na *btcwire.NetAddress) string { if Local(na) { return "local" } if !Routable(na) { return "unroutable" } if ipv4 := na.IP.To4(); ipv4 != nil { return (&net.IPNet{IP: na.IP, Mask: net.CIDRMask(16, 32)}).String() } if RFC6145(na) || RFC6052(na) { // last four bytes are the ip address ip := net.IP(na.IP[12:16]) return (&net.IPNet{IP: ip, Mask: net.CIDRMask(16, 32)}).String() } if RFC3964(na) { ip := net.IP(na.IP[2:7]) return (&net.IPNet{IP: ip, Mask: net.CIDRMask(16, 32)}).String() } if RFC4380(na) { // teredo tunnels have the last 4 bytes as the v4 address XOR // 0xff. ip := net.IP(make([]byte, 4)) for i, byte := range na.IP[12:16] { ip[i] = byte ^ 0xff } return (&net.IPNet{IP: ip, Mask: net.CIDRMask(16, 32)}).String() } // XXX tor? if Tor(na) { panic("oga should have implemented me") } // OK, so now we know ourselves to be a IPv6 address. // bitcoind uses /32 for everything but what it calls he.net, which is // it uses /36 for. he.net is actualy 2001:470::/32, whereas bitcoind // counts it as 2011:470::/32. bits := 32 heNet := &net.IPNet{IP: net.ParseIP("2011:470::"), Mask: net.CIDRMask(32, 128)} if heNet.Contains(na.IP) { bits = 36 } return (&net.IPNet{IP: na.IP, Mask: net.CIDRMask(bits, 128)}).String() }