Beispiel #1
0
// Parese network's "addr" message
func ParseAddr(pl []byte) {
	b := bytes.NewBuffer(pl)
	cnt, _ := btc.ReadVLen(b)
	for i := 0; i < int(cnt); i++ {
		var buf [30]byte
		n, e := b.Read(buf[:])
		if n != len(buf) || e != nil {
			common.CountSafe("AddrError")
			//println("ParseAddr:", n, e)
			break
		}
		a := peersdb.NewPeer(buf[:])
		if !sys.ValidIp4(a.Ip4[:]) {
			common.CountSafe("AddrInvalid")
		} else if time.Unix(int64(a.Time), 0).Before(time.Now().Add(time.Minute)) {
			if time.Now().Before(time.Unix(int64(a.Time), 0).Add(peersdb.ExpirePeerAfter)) {
				k := qdb.KeyType(a.UniqID())
				v := peersdb.PeerDB.Get(k)
				if v != nil {
					a.Banned = peersdb.NewPeer(v[:]).Banned
				}
				peersdb.PeerDB.Put(k, a.Bytes())
			} else {
				common.CountSafe("AddrStale")
			}
		} else {
			common.CountSafe("AddrInFuture")
		}
	}
}
Beispiel #2
0
// Handle incoming "tx" msg
func (c *OneConnection) ParseTxNet(pl []byte) {
	tid := btc.NewSha2Hash(pl)
	NeedThisTx(tid, func() {
		// This body is called with a locked TxMutex
		if uint32(len(pl)) > atomic.LoadUint32(&common.CFG.TXPool.MaxTxSize) {
			common.CountSafe("TxTooBig")
			RejectTx(tid, len(pl), TX_REJECTED_TOO_BIG)
			return
		}
		tx, le := btc.NewTx(pl)
		if tx == nil {
			RejectTx(tid, len(pl), TX_REJECTED_FORMAT)
			c.DoS("TxBroken")
			return
		}
		if le != len(pl) {
			RejectTx(tid, len(pl), TX_REJECTED_LEN_MISMATCH)
			c.DoS("TxLenMismatch")
			return
		}
		if len(tx.TxIn) < 1 {
			RejectTx(tid, len(pl), TX_REJECTED_EMPTY_INPUT)
			c.DoS("TxNoInputs")
			return
		}

		tx.Hash = tid
		select {
		case NetTxs <- &TxRcvd{conn: c, tx: tx, raw: pl}:
			TransactionsPending[tid.BIdx()] = true
		default:
			common.CountSafe("NetTxsFULL")
		}
	})
}
Beispiel #3
0
func retry_cached_blocks() bool {
	if len(network.CachedBlocks) == 0 {
		return false
	}
	accepted_cnt := 0
	for k, v := range network.CachedBlocks {
		common.Busy("Cache.CheckBlock " + v.Block.Hash.String())
		e, dos, maybelater := common.BlockChain.CheckBlock(v.Block)
		if e == nil {
			common.Busy("Cache.AcceptBlock " + v.Block.Hash.String())
			e := LocalAcceptBlock(v.Block, v.Conn)
			if e == nil {
				//fmt.Println("*** Old block accepted", common.BlockChain.BlockTreeEnd.Height)
				common.CountSafe("BlocksFromCache")
				delete(network.CachedBlocks, k)
				accepted_cnt++
				break // One at a time should be enough
			} else {
				fmt.Println("retry AcceptBlock:", e.Error())
				v.Conn.DoS("BadCachedBlock1")
				delete(network.CachedBlocks, k)
			}
		} else {
			if !maybelater {
				fmt.Println("retry CheckBlock:", e.Error())
				common.CountSafe("BadCachedBlocks")
				if dos {
					v.Conn.DoS("BadCachedBlock2")
				}
				delete(network.CachedBlocks, k)
			}
		}
	}
	return accepted_cnt > 0 && len(network.CachedBlocks) > 0
}
Beispiel #4
0
// This function is called from a net conn thread
func netBlockReceived(conn *OneConnection, b []byte) {
	bl, e := btc.NewBlock(b)
	if e != nil {
		conn.DoS("BrokenBlock")
		println("NewBlock:", e.Error())
		return
	}

	idx := bl.Hash.BIdx()
	MutexRcv.Lock()
	if rb, got := ReceivedBlocks[idx]; got {
		rb.Cnt++
		MutexRcv.Unlock()
		common.CountSafe("BlockSameRcvd")
		return
	}
	orb := &OneReceivedBlock{Time: time.Now()}
	if bip, ok := conn.GetBlockInProgress[idx]; ok {
		orb.TmDownload = orb.Time.Sub(bip.start)
		conn.Mutex.Lock()
		delete(conn.GetBlockInProgress, idx)
		conn.Mutex.Unlock()
	} else {
		common.CountSafe("UnxpectedBlockRcvd")
	}
	ReceivedBlocks[idx] = orb
	MutexRcv.Unlock()

	NetBlocks <- &BlockRcvd{Conn: conn, Block: bl}
}
Beispiel #5
0
func txChecker(h *btc.Uint256) bool {
	TxMutex.Lock()
	rec, ok := TransactionsToSend[h.BIdx()]
	TxMutex.Unlock()
	if ok && rec.Own != 0 {
		return false // Assume own txs as non-trusted
	}
	if ok {
		common.CountSafe("TxScrBoosted")
	} else {
		common.CountSafe("TxScrMissed")
	}
	return ok
}
Beispiel #6
0
// Called from the blockchain thread
func HandleNetBlock(newbl *network.BlockRcvd) {
	common.CountSafe("HandleNetBlock")
	bl := newbl.Block
	common.Busy("CheckBlock " + bl.Hash.String())
	e, dos, maybelater := common.BlockChain.CheckBlock(bl)
	if e != nil {
		if maybelater {
			network.AddBlockToCache(bl, newbl.Conn)
		} else {
			fmt.Println(dos, e.Error())
			if dos {
				newbl.Conn.DoS("CheckBlock")
			}
		}
	} else {
		common.Busy("LocalAcceptBlock " + bl.Hash.String())
		e = LocalAcceptBlock(bl, newbl.Conn)
		if e == nil {
			retryCachedBlocks = retry_cached_blocks()
		} else {
			fmt.Println("AcceptBlock:", e.Error())
			newbl.Conn.DoS("LocalAcceptBl")
		}
	}
}
Beispiel #7
0
func RetryWaitingForInput(wtg *OneWaitingList) {
	for k, t := range wtg.Ids {
		pendtxrcv := TransactionsRejected[k].Wait4Input.TxRcvd
		if HandleNetTx(pendtxrcv, true) {
			common.CountSafe("TxRetryAccepted")
			if common.DebugLevel > 0 {
				fmt.Println(pendtxrcv.tx.Hash.String(), "accepted after", time.Now().Sub(t).String())
			}
		} else {
			common.CountSafe("TxRetryRejected")
			if common.DebugLevel > 0 {
				fmt.Println(pendtxrcv.tx.Hash.String(), "still rejected", TransactionsRejected[k].Reason)
			}
		}
	}
}
Beispiel #8
0
func (c *OneConnection) DoS(why string) {
	common.CountSafe("Ban" + why)
	c.Mutex.Lock()
	c.banit = true
	c.broken = true
	c.Mutex.Unlock()
}
Beispiel #9
0
// This function should be called only when OutConsActive >= MaxOutCons
func drop_slowest_peer() {
	var worst_ping int
	var worst_conn *OneConnection
	Mutex_net.Lock()
	for _, v := range OpenCons {
		if v.Incoming && InConsActive < atomic.LoadUint32(&common.CFG.Net.MaxInCons) {
			// If this is an incoming connection, but we are not full yet, ignore it
			continue
		}
		v.Mutex.Lock()
		ap := v.GetAveragePing()
		v.Mutex.Unlock()
		if ap > worst_ping {
			worst_ping = ap
			worst_conn = v
		}
	}
	if worst_conn != nil {
		if common.DebugLevel > 0 {
			println("Droping slowest peer", worst_conn.PeerAddr.Ip(), "/", worst_ping, "ms")
		}
		worst_conn.Disconnect()
		common.CountSafe("PeersDropped")
	}
	Mutex_net.Unlock()
}
Beispiel #10
0
// Expire cached blocks
func ExpireCachedBlocks() {
	for k, v := range CachedBlocks {
		if v.Time.Add(ExpireCachedAfter).Before(time.Now()) {
			delete(CachedBlocks, k)
			common.CountSafe("BlockExpired")
		}
	}
}
Beispiel #11
0
// Called from network threads
func blockWanted(h []byte) (yes bool) {
	idx := btc.NewUint256(h).BIdx()
	MutexRcv.Lock()
	_, ok := ReceivedBlocks[idx]
	MutexRcv.Unlock()
	if !ok {
		if atomic.LoadUint32(&common.CFG.Net.MaxBlockAtOnce) == 0 || !blocksLimitReached(idx) {
			yes = true
			common.CountSafe("BlockWanted")
		} else {
			common.CountSafe("BlockInProgress")
		}
	} else {
		common.CountSafe("BlockUnwanted")
	}
	return
}
Beispiel #12
0
func (c *OneConnection) SendRawMsg(cmd string, pl []byte) (e error) {
	c.Mutex.Lock()

	if c.Send.Buf != nil {
		// Before adding more data to the buffer, check the limit
		if len(c.Send.Buf) > MaxSendBufferSize {
			c.Mutex.Unlock()
			if common.DebugLevel > 0 {
				println(c.PeerAddr.Ip(), "Peer Send Buffer Overflow")
			}
			c.Disconnect()
			common.CountSafe("PeerSendOverflow")
			return errors.New("Send buffer overflow")
		}
	} else {
		c.Send.LastSent = time.Now()
	}

	common.CountSafe("sent_" + cmd)
	common.CountSafeAdd("sbts_"+cmd, uint64(len(pl)))
	sbuf := make([]byte, 24+len(pl))

	c.LastCmdSent = cmd
	c.LastBtsSent = uint32(len(pl))

	binary.LittleEndian.PutUint32(sbuf[0:4], common.Version)
	copy(sbuf[0:4], common.Magic[:])
	copy(sbuf[4:16], cmd)
	binary.LittleEndian.PutUint32(sbuf[16:20], uint32(len(pl)))

	sh := btc.Sha2Sum(pl[:])
	copy(sbuf[20:24], sh[:4])
	copy(sbuf[24:], pl)

	c.Send.Buf = append(c.Send.Buf, sbuf...)

	if common.DebugLevel < 0 {
		fmt.Println(cmd, len(c.Send.Buf), "->", c.PeerAddr.Ip())
	}
	c.Mutex.Unlock()
	//println(len(c.Send.Buf), "queued for seding to", c.PeerAddr.Ip())
	return
}
Beispiel #13
0
func isRoutable(rec *OneTxToSend) bool {
	if !common.CFG.TXRoute.Enabled {
		common.CountSafe("TxRouteDisabled")
		rec.Blocked = TX_REJECTED_DISABLED
		return false
	}
	if uint32(len(rec.Data)) > atomic.LoadUint32(&common.CFG.TXRoute.MaxTxSize) {
		common.CountSafe("TxRouteTooBig")
		rec.Blocked = TX_REJECTED_TOO_BIG
		return false
	}
	if rec.Fee < (uint64(len(rec.Data)) * atomic.LoadUint64(&common.CFG.TXRoute.FeePerByte)) {
		common.CountSafe("TxRouteLowFee")
		rec.Blocked = TX_REJECTED_LOW_FEE
		return false
	}
	if rec.Minout < atomic.LoadUint64(&common.CFG.TXRoute.MinVoutValue) {
		common.CountSafe("TxRouteDust")
		rec.Blocked = TX_REJECTED_DUST
		return false
	}
	return true
}
Beispiel #14
0
// This function is called from the main thread (or from an UI)
func NetRouteInv(typ uint32, h *btc.Uint256, fromConn *OneConnection) (cnt uint) {
	common.CountSafe(fmt.Sprint("NetRouteInv", typ))

	// Prepare the inv
	inv := new([36]byte)
	binary.LittleEndian.PutUint32(inv[0:4], typ)
	copy(inv[4:36], h.Bytes())

	// Append it to PendingInvs in each open connection
	Mutex_net.Lock()
	for _, v := range OpenCons {
		if v != fromConn { // except the one that this inv came from
			v.Mutex.Lock()
			if v.Node.DoNotRelayTxs && typ == 1 {
				// This node does not want tx inv (it came with its version message)
				common.CountSafe("SendInvNoTxNode")
			} else {
				if fromConn == nil && v.InvsRecieved == 0 {
					// Do not broadcast own txs to nodes that never sent any invs to us
					common.CountSafe("SendInvOwnBlocked")
				} else if len(v.PendingInvs) < 500 {
					v.PendingInvs = append(v.PendingInvs, inv)
					cnt++
				} else {
					common.CountSafe("SendInvIgnored")
				}
			}
			v.Mutex.Unlock()
		}
	}
	Mutex_net.Unlock()
	if cnt == 0 {
		NetAlerts <- "WARNING: your tx has not been broadcasted to any peer"
	}
	return
}
Beispiel #15
0
func (c *OneConnection) GetBlocks(pl []byte) {
	h2get, hashstop, e := parseLocatorsPayload(pl)

	if e != nil || len(h2get) < 1 || hashstop == nil {
		println("GetBlocks: error parsing payload from", c.PeerAddr.Ip())
		c.DoS("BadGetBlks")
		return
	}

	invs := make(map[[32]byte]bool, 500)
	for i := range h2get {
		common.BlockChain.BlockIndexAccess.Lock()
		if bl, ok := common.BlockChain.BlockIndex[h2get[i].BIdx()]; ok {
			// make sure that this block is in our main chain
			common.Last.Mutex.Lock()
			end := common.Last.Block
			common.Last.Mutex.Unlock()
			for ; end != nil && end.Height >= bl.Height; end = end.Parent {
				if end == bl {
					addInvBlockBranch(invs, bl, hashstop) // Yes - this is the main chain
					if common.DebugLevel > 0 {
						fmt.Println(c.PeerAddr.Ip(), "getblocks from", bl.Height,
							"stop at", hashstop.String(), "->", len(invs), "invs")
					}

					if len(invs) > 0 {
						common.BlockChain.BlockIndexAccess.Unlock()

						inv := new(bytes.Buffer)
						btc.WriteVlen(inv, uint64(len(invs)))
						for k, _ := range invs {
							binary.Write(inv, binary.LittleEndian, uint32(2))
							inv.Write(k[:])
						}
						c.SendRawMsg("inv", inv.Bytes())
						return
					}
				}
			}
		}
		common.BlockChain.BlockIndexAccess.Unlock()
	}

	common.CountSafe("GetblksMissed")
	return
}
Beispiel #16
0
// This one shall only be called from the chain thread (this no protection)
func AddBlockToCache(bl *btc.Block, conn *OneConnection) {
	// we use CachedBlocks only from one therad so no need for a mutex
	if len(CachedBlocks) == common.MaxCachedBlocks {
		// Remove the oldest one
		oldest := time.Now()
		var todel [btc.Uint256IdxLen]byte
		for k, v := range CachedBlocks {
			if v.Time.Before(oldest) {
				oldest = v.Time
				todel = k
			}
		}
		delete(CachedBlocks, todel)
		common.CountSafe("BlockCacheFull")
	}
	CachedBlocks[bl.Hash.BIdx()] = OneCachedBlock{Time: time.Now(), Block: bl, Conn: conn}
}
Beispiel #17
0
func (c *OneConnection) ProcessInv(pl []byte) {
	if len(pl) < 37 {
		println(c.PeerAddr.Ip(), "inv payload too short", len(pl))
		return
	}
	c.InvsRecieved++

	cnt, of := btc.VLen(pl)
	if len(pl) != of+36*cnt {
		println("inv payload length mismatch", len(pl), of, cnt)
	}

	var blinv2ask []byte

	for i := 0; i < cnt; i++ {
		typ := binary.LittleEndian.Uint32(pl[of : of+4])
		common.CountSafe(fmt.Sprint("InvGot", typ))
		if typ == 2 {
			if blockWanted(pl[of+4 : of+36]) {
				blinv2ask = append(blinv2ask, pl[of+4:of+36]...)
			}
		} else if typ == 1 {
			if common.CFG.TXPool.Enabled {
				c.TxInvNotify(pl[of+4 : of+36])
			}
		}
		of += 36
	}

	if len(blinv2ask) > 0 {
		bu := new(bytes.Buffer)
		btc.WriteVlen(bu, uint64(len(blinv2ask)/32))
		for i := 0; i < len(blinv2ask); i += 32 {
			bh := btc.NewUint256(blinv2ask[i : i+32])
			c.Mutex.Lock()
			c.GetBlockInProgress[bh.BIdx()] = &oneBlockDl{hash: bh, start: time.Now()}
			c.Mutex.Unlock()
			binary.Write(bu, binary.LittleEndian, uint32(2))
			bu.Write(bh.Hash[:])
		}
		c.SendRawMsg("getdata", bu.Bytes())
	}

	return
}
Beispiel #18
0
// This function is called for each tx mined in a new block
func TxMined(tx *btc.Tx) {
	h := tx.Hash
	TxMutex.Lock()
	if rec, ok := TransactionsToSend[h.BIdx()]; ok {
		common.CountSafe("TxMinedToSend")
		deleteToSend(rec)
	}
	if _, ok := TransactionsRejected[h.BIdx()]; ok {
		common.CountSafe("TxMinedRejected")
		deleteRejected(h.BIdx())
	}
	if _, ok := TransactionsPending[h.BIdx()]; ok {
		common.CountSafe("TxMinedPending")
		delete(TransactionsPending, h.BIdx())
	}

	// Go through all the inputs and make sure we are not leaving them in SpentOutputs
	for i := range tx.TxIn {
		idx := tx.TxIn[i].Input.UIdx()
		if val, ok := SpentOutputs[idx]; ok {
			if rec, _ := TransactionsToSend[val]; rec != nil {
				if rec.Own != 0 {
					common.CountSafe("TxMinedMalleabled")
					NetAlerts <- fmt.Sprint("Input from own ", rec.Tx.Hash.String(), " mined in ", tx.Hash.String())
				} else {
					common.CountSafe("TxMinedOtherSpend")
				}
				deleteToSend(rec)
			} else {
				common.CountSafe("TxMinedSpentERROR")
				NetAlerts <- fmt.Sprint("WTF? Input from ", rec.Tx.Hash.String(), " in mem-spent, but tx not in the mem-pool")
			}
			delete(SpentOutputs, idx)
		}
	}

	wtg := WaitingForInputs[h.BIdx()]
	TxMutex.Unlock()

	// Try to redo waiting txs
	if wtg != nil {
		common.CountSafe("TxMinedGotInput")
		RetryWaitingForInput(wtg)
	}
}
Beispiel #19
0
// Return false if we do not want to receive a data for this tx
func NeedThisTx(id *btc.Uint256, cb func()) (res bool) {
	TxMutex.Lock()
	if _, present := TransactionsToSend[id.BIdx()]; present {
		//res = false
	} else if _, present := TransactionsRejected[id.BIdx()]; present {
		//res = false
	} else if _, present := TransactionsPending[id.BIdx()]; present {
		//res = false
	} else if txo, _ := common.BlockChain.Unspent.UnspentGet(&btc.TxPrevOut{Hash: id.Hash}); txo != nil {
		// This assumes that tx's out #0 has not been spent yet, which may not always be the case, but well...
		common.CountSafe("TxMinedRejected")
	} else {
		res = true
		if cb != nil {
			cb()
		}
	}
	TxMutex.Unlock()
	return
}
Beispiel #20
0
func DoNetwork(ad *peersdb.PeerAddr) {
	var e error
	conn := NewConnection(ad)
	Mutex_net.Lock()
	if _, ok := OpenCons[ad.UniqID()]; ok {
		if common.DebugLevel > 0 {
			fmt.Println(ad.Ip(), "already connected")
		}
		common.CountSafe("ConnectingAgain")
		Mutex_net.Unlock()
		return
	}
	OpenCons[ad.UniqID()] = conn
	OutConsActive++
	Mutex_net.Unlock()
	go func() {
		conn.NetConn, e = net.DialTimeout("tcp4", fmt.Sprintf("%d.%d.%d.%d:%d",
			ad.Ip4[0], ad.Ip4[1], ad.Ip4[2], ad.Ip4[3], ad.Port), TCPDialTimeout)
		if e == nil {
			conn.ConnectedAt = time.Now()
			if common.DebugLevel > 0 {
				println("Connected to", ad.Ip())
			}
			conn.Run()
		} else {
			if common.DebugLevel > 0 {
				println("Could not connect to", ad.Ip())
			}
			//println(e.Error())
		}
		Mutex_net.Lock()
		delete(OpenCons, ad.UniqID())
		OutConsActive--
		Mutex_net.Unlock()
		ad.Dead()
	}()
}
Beispiel #21
0
func BestExternalAddr() []byte {
	var best_ip, worst_ip uint32
	var best_cnt, worst_tim uint

	ExternalIpMutex.Lock()

	if len(ExternalIp4) > 0 {
		for ip, rec := range ExternalIp4 {
			if worst_tim == 0 {
				worst_tim = rec[1]
				worst_ip = ip
			}
			if rec[0] > best_cnt {
				best_cnt = rec[0]
				best_ip = ip
			} else if rec[1] < worst_tim {
				worst_tim = rec[1]
				worst_ip = ip
			}
		}

		// Expire any extra IP if it has been stale for more than an hour
		if len(ExternalIp4) > 1 && uint(time.Now().Unix())-worst_tim > 3600 {
			common.CountSafe("ExternalIPExpire")
			delete(ExternalIp4, worst_ip)
		}
	}

	ExternalIpMutex.Unlock()
	res := make([]byte, 26)
	binary.LittleEndian.PutUint64(res[0:8], common.Services)
	// leave ip6 filled with zeros, except for the last 2 bytes:
	res[18], res[19] = 0xff, 0xff
	binary.BigEndian.PutUint32(res[20:24], best_ip)
	binary.BigEndian.PutUint16(res[24:26], common.DefaultTcpPort)
	return res
}
Beispiel #22
0
func SendInvToRandomPeer(typ uint32, h *btc.Uint256) {
	common.CountSafe(fmt.Sprint("NetSendOneInv", typ))

	// Prepare the inv
	inv := new([36]byte)
	binary.LittleEndian.PutUint32(inv[0:4], typ)
	copy(inv[4:36], h.Bytes())

	// Append it to PendingInvs in a random connection
	network.Mutex_net.Lock()
	idx := rand.Intn(len(network.OpenCons))
	var cnt int
	for _, v := range network.OpenCons {
		if idx == cnt {
			v.Mutex.Lock()
			v.PendingInvs = append(v.PendingInvs, inv)
			v.Mutex.Unlock()
			break
		}
		cnt++
	}
	network.Mutex_net.Unlock()
	return
}
Beispiel #23
0
// Process that handles communication with a single peer
func (c *OneConnection) Run() {
	c.SendVersion()

	c.Mutex.Lock()
	c.LastDataGot = time.Now()
	c.NextBlocksAsk = time.Now()                 // ask for blocks ASAP
	c.NextGetAddr = time.Now()                   // do getaddr ~10 seconds from now
	c.NextPing = time.Now().Add(5 * time.Second) // do first ping ~5 seconds from now
	c.Mutex.Unlock()

	for !c.IsBroken() {
		c.Mutex.Lock()
		c.LoopCnt++
		c.Mutex.Unlock()

		cmd := c.FetchMessage()
		if c.IsBroken() {
			break
		}

		// Timeout ping in progress
		if c.PingInProgress != nil && time.Now().After(c.LastPingSent.Add(PingTimeout)) {
			if common.DebugLevel > 0 {
				println(c.PeerAddr.Ip(), "ping timeout")
			}
			common.CountSafe("PingTimeout")
			c.HandlePong() // this will set LastPingSent to nil
		}

		if cmd == nil {
			c.Tick()
			continue
		}

		c.Mutex.Lock()
		c.LastDataGot = time.Now()
		c.LastCmdRcvd = cmd.cmd
		c.LastBtsRcvd = uint32(len(cmd.pl))
		c.Mutex.Unlock()

		c.PeerAddr.Alive()
		if common.DebugLevel < 0 {
			fmt.Println(c.PeerAddr.Ip(), "->", cmd.cmd, len(cmd.pl))
		}

		if c.Send.Buf != nil && len(c.Send.Buf) > SendBufSizeHoldOn {
			common.CountSafe("hold_" + cmd.cmd)
			common.CountSafeAdd("hbts_"+cmd.cmd, uint64(len(cmd.pl)))
			continue
		}

		common.CountSafe("rcvd_" + cmd.cmd)
		common.CountSafeAdd("rbts_"+cmd.cmd, uint64(len(cmd.pl)))

		switch cmd.cmd {
		case "version":
			er := c.HandleVersion(cmd.pl)
			if er != nil {
				println("version:", er.Error())
				c.Disconnect()
			}

		case "verack":
			c.VerackReceived = true
			if common.IsListenTCP() {
				c.SendOwnAddr()
			}

		case "inv":
			c.ProcessInv(cmd.pl)

		case "tx":
			if common.CFG.TXPool.Enabled {
				c.ParseTxNet(cmd.pl)
			}

		case "addr":
			ParseAddr(cmd.pl)

		case "block": //block received
			netBlockReceived(c, cmd.pl)

		case "getblocks":
			c.GetBlocks(cmd.pl)

		case "getdata":
			c.ProcessGetData(cmd.pl)

		case "getaddr":
			c.SendAddr()

		case "alert":
			c.HandleAlert(cmd.pl)

		case "ping":
			re := make([]byte, len(cmd.pl))
			copy(re, cmd.pl)
			c.SendRawMsg("pong", re)

		case "pong":
			if c.PingInProgress == nil {
				common.CountSafe("PongUnexpected")
			} else if bytes.Equal(cmd.pl, c.PingInProgress) {
				c.HandlePong()
			} else {
				common.CountSafe("PongMismatch")
			}

		case "getheaders":
			c.GetHeaders(cmd.pl)

		case "notfound":
			common.CountSafe("NotFound")

		default:
			if common.DebugLevel > 0 {
				println(cmd.cmd, "from", c.PeerAddr.Ip())
			}
		}
	}
	c.Mutex.Lock()
	ban := c.banit
	c.Mutex.Unlock()
	if ban {
		c.PeerAddr.Ban()
		common.CountSafe("PeersBanned")
	} else if c.Incoming {
		HammeringMutex.Lock()
		RecentlyDisconencted[c.PeerAddr.NetAddr.Ip4] = time.Now()
		HammeringMutex.Unlock()
	}
	if common.DebugLevel > 0 {
		println("Disconnected from", c.PeerAddr.Ip())
	}
	c.NetConn.Close()
}
Beispiel #24
0
// TCP server
func tcp_server() {
	ad, e := net.ResolveTCPAddr("tcp4", fmt.Sprint("0.0.0.0:", common.DefaultTcpPort))
	if e != nil {
		println("ResolveTCPAddr", e.Error())
		return
	}

	lis, e := net.ListenTCP("tcp4", ad)
	if e != nil {
		println("ListenTCP", e.Error())
		return
	}
	defer lis.Close()

	//fmt.Println("TCP server started at", ad.String())

	for common.IsListenTCP() {
		common.CountSafe("NetServerLoops")
		Mutex_net.Lock()
		ica := InConsActive
		Mutex_net.Unlock()
		if ica < atomic.LoadUint32(&common.CFG.Net.MaxInCons) {
			lis.SetDeadline(time.Now().Add(time.Second))
			tc, e := lis.AcceptTCP()
			if e == nil {
				var terminate bool

				if common.DebugLevel > 0 {
					fmt.Println("Incoming connection from", tc.RemoteAddr().String())
				}
				ad, e := peersdb.NewPeerFromString(tc.RemoteAddr().String())
				if e == nil {
					// Hammering protection
					HammeringMutex.Lock()
					ti, ok := RecentlyDisconencted[ad.NetAddr.Ip4]
					HammeringMutex.Unlock()
					if ok && time.Now().Sub(ti) < HammeringMinReconnect {
						//println(ad.Ip(), "is hammering within", time.Now().Sub(ti).String())
						common.CountSafe("InConnHammer")
						ad.Ban()
						terminate = true
					}

					if !terminate {
						// Incoming IP passed all the initial checks - talk to it
						conn := NewConnection(ad)
						conn.ConnectedAt = time.Now()
						conn.Incoming = true
						conn.NetConn = tc
						Mutex_net.Lock()
						if _, ok := OpenCons[ad.UniqID()]; ok {
							//fmt.Println(ad.Ip(), "already connected")
							common.CountSafe("SameIpReconnect")
							Mutex_net.Unlock()
							terminate = true
						} else {
							OpenCons[ad.UniqID()] = conn
							InConsActive++
							Mutex_net.Unlock()
							go func() {
								conn.Run()
								Mutex_net.Lock()
								delete(OpenCons, ad.UniqID())
								InConsActive--
								Mutex_net.Unlock()
							}()
						}
					}
				} else {
					if common.DebugLevel > 0 {
						println("NewPeerFromString:", e.Error())
					}
					common.CountSafe("InConnRefused")
					terminate = true
				}

				// had any error occured - close teh TCP connection
				if terminate {
					tc.Close()
				}
			}
		} else {
			time.Sleep(1e9)
		}
	}
	Mutex_net.Lock()
	for _, c := range OpenCons {
		if c.Incoming {
			c.Disconnect()
		}
	}
	TCPServerStarted = false
	Mutex_net.Unlock()
	//fmt.Println("TCP server stopped")
}
Beispiel #25
0
func (c *OneConnection) Tick() {
	c.Mutex.Lock()
	c.TicksCnt++
	c.Mutex.Unlock()

	// Disconnect and ban useless peers (sych that don't send invs)
	if c.InvsRecieved == 0 && c.ConnectedAt.Add(15*time.Minute).Before(time.Now()) {
		c.DoS("PeerUseless")
		return
	}

	// Check no-data timeout
	if c.LastDataGot.Add(NoDataTimeout).Before(time.Now()) {
		c.Disconnect()
		common.CountSafe("NetNodataTout")
		if common.DebugLevel > 0 {
			println(c.PeerAddr.Ip(), "no data for", NoDataTimeout/time.Second, "seconds - disconnect")
		}
		return
	}

	if c.Send.Buf != nil {
		n, e := common.SockWrite(c.NetConn, c.Send.Buf)
		if n > 0 {
			c.Mutex.Lock()
			c.Send.LastSent = time.Now()
			c.BytesSent += uint64(n)
			if n >= len(c.Send.Buf) {
				c.Send.Buf = nil
			} else {
				tmp := make([]byte, len(c.Send.Buf)-n)
				copy(tmp, c.Send.Buf[n:])
				c.Send.Buf = tmp
			}
			c.Mutex.Unlock()
		} else if time.Now().After(c.Send.LastSent.Add(AnySendTimeout)) {
			common.CountSafe("PeerSendTimeout")
			c.Disconnect()
		} else if e != nil {
			if common.DebugLevel > 0 {
				println(c.PeerAddr.Ip(), "Connection Broken during send")
			}
			c.Disconnect()
		}
		return
	}

	if !c.VerackReceived {
		// If we have no ack, do nothing more.
		return
	}

	// Ask node for new addresses...?
	if time.Now().After(c.NextGetAddr) {
		if peersdb.PeerDB.Count() > common.MaxPeersNeeded {
			// If we have a lot of peers, do not ask for more, to save bandwidth
			common.CountSafe("AddrEnough")
		} else {
			common.CountSafe("AddrWanted")
			c.SendRawMsg("getaddr", nil)
		}
		c.NextGetAddr = time.Now().Add(AskAddrsEvery)
		return
	}

	// Need to send some invs...?
	if c.SendInvs() {
		return
	}

	// Timeout getdata for blocks in progress, so the map does not grow to infinity
	for k, v := range c.GetBlockInProgress {
		if time.Now().After(v.start.Add(GetBlockTimeout)) {
			common.CountSafe("BlockGetTimeout")
			c.Mutex.Lock()
			delete(c.GetBlockInProgress, k)
			c.Mutex.Unlock()
		}
	}

	// Need to send getblocks...?
	if len(c.GetBlockInProgress) == 0 && c.getblocksNeeded() {
		return
	}

	// Ping if we dont do anything
	c.TryPing()
}
Beispiel #26
0
func (c *OneConnection) FetchMessage() *BCmsg {
	var e error
	var n int

	for c.recv.hdr_len < 24 {
		n, e = common.SockRead(c.NetConn, c.recv.hdr[c.recv.hdr_len:24])
		c.Mutex.Lock()
		c.recv.hdr_len += n
		if e != nil {
			c.Mutex.Unlock()
			c.HandleError(e)
			return nil
		}
		if c.recv.hdr_len >= 4 && !bytes.Equal(c.recv.hdr[:4], common.Magic[:]) {
			c.Mutex.Unlock()
			if common.DebugLevel > 0 {
				println("FetchMessage: Proto out of sync")
			}
			common.CountSafe("NetBadMagic")
			c.Disconnect()
			return nil
		}
		if c.broken {
			c.Mutex.Unlock()
			return nil
		}
		if c.recv.hdr_len >= 24 {
			c.recv.pl_len = binary.LittleEndian.Uint32(c.recv.hdr[16:20])
			c.recv.cmd = strings.TrimRight(string(c.recv.hdr[4:16]), "\000")
		}
		c.Mutex.Unlock()
	}

	if c.recv.pl_len > 0 {
		if c.recv.dat == nil {
			msi := maxmsgsize(c.recv.cmd)
			if c.recv.pl_len > msi {
				//println(c.PeerAddr.Ip(), "Command", c.recv.cmd, "is going to be too big", c.recv.pl_len, msi)
				c.DoS("MsgTooBig")
				return nil
			}
			c.Mutex.Lock()
			c.recv.dat = make([]byte, c.recv.pl_len)
			c.recv.datlen = 0
			c.Mutex.Unlock()
		}
		for c.recv.datlen < c.recv.pl_len {
			n, e = common.SockRead(c.NetConn, c.recv.dat[c.recv.datlen:])
			if n > 0 {
				c.Mutex.Lock()
				c.recv.datlen += uint32(n)
				c.Mutex.Unlock()
				if c.recv.datlen > c.recv.pl_len {
					println(c.PeerAddr.Ip(), "is sending more of", c.recv.cmd, "then it should have", c.recv.datlen, c.recv.pl_len)
					c.DoS("MsgSizeMismatch")
					return nil
				}
			}
			if e != nil {
				c.HandleError(e)
				return nil
			}
			if c.broken {
				return nil
			}
		}
	}

	sh := btc.Sha2Sum(c.recv.dat)
	if !bytes.Equal(c.recv.hdr[20:24], sh[:4]) {
		//println(c.PeerAddr.Ip(), "Msg checksum error")
		c.DoS("MsgBadChksum")
		return nil
	}

	ret := new(BCmsg)
	ret.cmd = c.recv.cmd
	ret.pl = c.recv.dat

	c.Mutex.Lock()
	c.recv.dat = nil
	c.recv.hdr_len = 0
	c.BytesReceived += uint64(24 + len(ret.pl))
	c.Mutex.Unlock()

	return ret
}
Beispiel #27
0
func (c *OneConnection) ProcessGetData(pl []byte) {
	var notfound []byte

	//println(c.PeerAddr.Ip(), "getdata")
	b := bytes.NewReader(pl)
	cnt, e := btc.ReadVLen(b)
	if e != nil {
		println("ProcessGetData:", e.Error(), c.PeerAddr.Ip())
		return
	}
	for i := 0; i < int(cnt); i++ {
		var typ uint32
		var h [36]byte

		n, _ := b.Read(h[:])
		if n != 36 {
			println("ProcessGetData: pl too short", c.PeerAddr.Ip())
			return
		}

		typ = binary.LittleEndian.Uint32(h[:4])

		common.CountSafe(fmt.Sprint("GetdataType", typ))
		if typ == 2 {
			uh := btc.NewUint256(h[4:])
			bl, _, er := common.BlockChain.Blocks.BlockGet(uh)
			if er == nil {
				c.SendRawMsg("block", bl)
			} else {
				notfound = append(notfound, h[:]...)
			}
		} else if typ == 1 {
			// transaction
			uh := btc.NewUint256(h[4:])
			TxMutex.Lock()
			if tx, ok := TransactionsToSend[uh.BIdx()]; ok && tx.Blocked == 0 {
				tx.SentCnt++
				tx.Lastsent = time.Now()
				TxMutex.Unlock()
				c.SendRawMsg("tx", tx.Data)
			} else {
				TxMutex.Unlock()
				notfound = append(notfound, h[:]...)
			}
		} else {
			if common.DebugLevel > 0 {
				println("getdata for type", typ, "not supported yet")
			}
			if typ > 0 && typ <= 3 /*3 is a filtered block(we dont support it)*/ {
				notfound = append(notfound, h[:]...)
			}
		}
	}

	if len(notfound) > 0 {
		buf := new(bytes.Buffer)
		btc.WriteVlen(buf, uint64(len(notfound)/36))
		buf.Write(notfound)
		c.SendRawMsg("notfound", buf.Bytes())
	}
}
Beispiel #28
0
// Must be called from the chain's thread
func HandleNetTx(ntx *TxRcvd, retry bool) (accepted bool) {
	common.CountSafe("HandleNetTx")

	tx := ntx.tx
	var totinp, totout uint64
	var frommem bool

	TxMutex.Lock()

	if !retry {
		if _, present := TransactionsPending[tx.Hash.BIdx()]; !present {
			// It had to be mined in the meantime, so just drop it now
			TxMutex.Unlock()
			common.CountSafe("TxNotPending")
			return
		}
		delete(TransactionsPending, ntx.tx.Hash.BIdx())
	} else {
		// In case case of retry, it is on the rejected list,
		// ... so remove it now to free any tied WaitingForInputs
		deleteRejected(tx.Hash.BIdx())
	}

	pos := make([]*btc.TxOut, len(tx.TxIn))
	spent := make([]uint64, len(tx.TxIn))

	// Check if all the inputs exist in the chain
	for i := range tx.TxIn {
		spent[i] = tx.TxIn[i].Input.UIdx()

		if _, ok := SpentOutputs[spent[i]]; ok {
			RejectTx(ntx.tx.Hash, len(ntx.raw), TX_REJECTED_DOUBLE_SPEND)
			TxMutex.Unlock()
			common.CountSafe("TxRejectedDoubleSpnd")
			return
		}

		inptx := btc.NewUint256(tx.TxIn[i].Input.Hash[:])
		if txinmem, ok := TransactionsToSend[inptx.BIdx()]; common.CFG.TXPool.AllowMemInputs && ok {
			if int(tx.TxIn[i].Input.Vout) >= len(txinmem.TxOut) {
				RejectTx(ntx.tx.Hash, len(ntx.raw), TX_REJECTED_BAD_INPUT)
				TxMutex.Unlock()
				common.CountSafe("TxRejectedBadInput")
				return
			}
			pos[i] = txinmem.TxOut[tx.TxIn[i].Input.Vout]
			common.CountSafe("TxInputInMemory")
			frommem = true
		} else {
			pos[i], _ = common.BlockChain.Unspent.UnspentGet(&tx.TxIn[i].Input)
			if pos[i] == nil {
				var newone bool

				if !common.CFG.TXPool.AllowMemInputs {
					RejectTx(ntx.tx.Hash, len(ntx.raw), TX_REJECTED_NOT_MINED)
					TxMutex.Unlock()
					common.CountSafe("TxRejectedMemInput")
					return
				}
				// In this case, let's "save" it for later...
				missingid := btc.NewUint256(tx.TxIn[i].Input.Hash[:])
				nrtx := RejectTx(ntx.tx.Hash, len(ntx.raw), TX_REJECTED_NO_TXOU)

				if nrtx != nil {
					nrtx.Wait4Input = &Wait4Input{missingTx: missingid, TxRcvd: ntx}

					// Add to waiting list:
					var rec *OneWaitingList
					if rec, _ = WaitingForInputs[nrtx.Wait4Input.missingTx.BIdx()]; rec == nil {
						rec = new(OneWaitingList)
						rec.TxID = nrtx.Wait4Input.missingTx
						rec.Ids = make(map[[btc.Uint256IdxLen]byte]time.Time)
						newone = true
					}
					rec.Ids[tx.Hash.BIdx()] = time.Now()
					WaitingForInputs[nrtx.Wait4Input.missingTx.BIdx()] = rec
				}

				TxMutex.Unlock()
				if newone {
					common.CountSafe("TxRejectedNoInpNew")
				} else {
					common.CountSafe("TxRejectedNoInpOld")
				}
				return
			}
		}
		totinp += pos[i].Value
	}

	// Check if total output value does not exceed total input
	minout := uint64(btc.MAX_MONEY)
	for i := range tx.TxOut {
		if tx.TxOut[i].Value < atomic.LoadUint64(&common.CFG.TXPool.MinVoutValue) {
			RejectTx(ntx.tx.Hash, len(ntx.raw), TX_REJECTED_DUST)
			TxMutex.Unlock()
			common.CountSafe("TxRejectedDust")
			return
		}
		if tx.TxOut[i].Value < minout {
			minout = tx.TxOut[i].Value
		}
		totout += tx.TxOut[i].Value
	}

	if totout > totinp {
		RejectTx(ntx.tx.Hash, len(ntx.raw), TX_REJECTED_OVERSPEND)
		TxMutex.Unlock()
		ntx.conn.DoS("TxOverspend")
		return
	}

	// Check for a proper fee
	fee := totinp - totout
	if fee < (uint64(len(ntx.raw)) * atomic.LoadUint64(&common.CFG.TXPool.FeePerByte)) {
		RejectTx(ntx.tx.Hash, len(ntx.raw), TX_REJECTED_LOW_FEE)
		TxMutex.Unlock()
		common.CountSafe("TxRejectedLowFee")
		return
	}

	// Verify scripts
	for i := range tx.TxIn {
		if !script.VerifyTxScript(tx.TxIn[i].ScriptSig, pos[i].Pk_script, i, tx, true) {
			RejectTx(ntx.tx.Hash, len(ntx.raw), TX_REJECTED_SCRIPT_FAIL)
			TxMutex.Unlock()
			ntx.conn.DoS("TxScriptFail")
			return
		}
	}

	rec := &OneTxToSend{Data: ntx.raw, Spent: spent, Volume: totinp, Fee: fee, Firstseen: time.Now(), Tx: tx, Minout: minout}
	TransactionsToSend[tx.Hash.BIdx()] = rec
	for i := range spent {
		SpentOutputs[spent[i]] = tx.Hash.BIdx()
	}

	wtg := WaitingForInputs[tx.Hash.BIdx()]
	if wtg != nil {
		defer RetryWaitingForInput(wtg) // Redo waiting txs when leaving this function
	}

	TxMutex.Unlock()
	common.CountSafe("TxAccepted")

	if frommem {
		// Gocoin does not route txs that need unconfirmed inputs
		rec.Blocked = TX_REJECTED_NOT_MINED
		common.CountSafe("TxRouteNotMined")
	} else if isRoutable(rec) {
		rec.Invsentcnt += NetRouteInv(1, tx.Hash, ntx.conn)
		common.CountSafe("TxRouteOK")
	}

	accepted = true
	return
}
Beispiel #29
0
func main() {
	var ptr *byte
	if unsafe.Sizeof(ptr) < 8 {
		fmt.Println("WARNING: Gocoin client shall be build for 64-bit arch. It will likely crash now.")
	}

	fmt.Println("Gocoin client version", lib.Version)
	runtime.GOMAXPROCS(runtime.NumCPU()) // It seems that Go does not do it by default

	// Disable Ctrl+C
	signal.Notify(killchan, os.Interrupt, os.Kill)
	defer func() {
		if r := recover(); r != nil {
			err, ok := r.(error)
			if !ok {
				err = fmt.Errorf("pkg: %v", r)
			}
			fmt.Println("main panic recovered:", err.Error())
			fmt.Println(string(debug.Stack()))
			network.NetCloseAll()
			common.CloseBlockChain()
			peersdb.ClosePeerDB()
			sys.UnlockDatabaseDir()
			os.Exit(1)
		}
	}()

	common.InitConfig()
	host_init() // This will create the DB lock file and keep it open

	peersTick := time.Tick(5 * time.Minute)
	txPoolTick := time.Tick(time.Minute)
	netTick := time.Tick(time.Second)

	peersdb.Testnet = common.Testnet
	peersdb.ConnectOnly = common.CFG.ConnectOnly
	peersdb.Services = common.Services
	peersdb.InitPeers(common.GocoinHomeDir)

	common.Last.Block = common.BlockChain.BlockTreeEnd
	common.Last.Time = time.Unix(int64(common.Last.Block.Timestamp()), 0)
	if common.Last.Time.After(time.Now()) {
		common.Last.Time = time.Now()
	}

	for k, v := range common.BlockChain.BlockIndex {
		network.ReceivedBlocks[k] = &network.OneReceivedBlock{Time: time.Unix(int64(v.Timestamp()), 0)}
	}

	if common.CFG.TextUI.Enabled {
		go textui.MainThread()
	}

	if common.CFG.WebUI.Interface != "" {
		fmt.Println("Starting WebUI at", common.CFG.WebUI.Interface, "...")
		go webui.ServerThread(common.CFG.WebUI.Interface)
	}

	for !usif.Exit_now {
		common.CountSafe("MainThreadLoops")
		for retryCachedBlocks {
			retryCachedBlocks = retry_cached_blocks()
			// We have done one per loop - now do something else if pending...
			if len(network.NetBlocks) > 0 || len(usif.UiChannel) > 0 {
				break
			}
		}

		common.Busy("")

		select {
		case s := <-killchan:
			fmt.Println("Got signal:", s)
			usif.Exit_now = true
			continue

		case newbl := <-network.NetBlocks:
			common.CountSafe("MainNetBlock")
			HandleNetBlock(newbl)

		case newtx := <-network.NetTxs:
			common.CountSafe("MainNetTx")
			network.HandleNetTx(newtx, false)

		case newal := <-network.NetAlerts:
			common.CountSafe("MainNetAlert")
			fmt.Println("\007" + newal)
			textui.ShowPrompt()

		case <-netTick:
			common.CountSafe("MainNetTick")
			network.NetworkTick()

		case cmd := <-usif.UiChannel:
			common.CountSafe("MainUICmd")
			common.Busy("UI command")
			cmd.Handler(cmd.Param)
			cmd.Done.Done()
			continue

		case <-peersTick:
			peersdb.ExpirePeers()

		case <-txPoolTick:
			network.ExpireTxs()

		case <-time.After(time.Second / 2):
			common.CountSafe("MainThreadTouts")
			if !retryCachedBlocks {
				common.Busy("common.BlockChain.Idle()")
				if common.BlockChain.Idle() {
					common.CountSafe("ChainIdleUsed")
				}
			}
			continue
		}
	}

	network.NetCloseAll()
	peersdb.ClosePeerDB()

	if usif.DefragBlocksDB != 0 {
		defrag_db()
	}

	common.CloseBlockChain()
	sys.UnlockDatabaseDir()
}