// Copyright (c) 2009-2010 Satoshi Nakamoto // Copyright (c) 2009-2012 The Bitcoin developers // Distributed under the MIT/X11 software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #ifndef BITCOIN_NET_H #define BITCOIN_NET_H #include #include #include #include #include #ifndef WIN32 #include #endif #include "mruset.h" #include "limitedmap.h" #include "netbase.h" #include "protocol.h" #include "addrman.h" #include "hash.h" #include "bloom.h" /** The maximum number of entries in an 'inv' protocol message */ static const unsigned int MAX_INV_SZ = 50000; class CNode; class CBlockIndex; extern int nBestHeight; inline unsigned int ReceiveFloodSize() { return 1000*GetArg("-maxreceivebuffer", 5*1000); } inline unsigned int SendBufferSize() { return 1000*GetArg("-maxsendbuffer", 1*1000); } void AddOneShot(std::string strDest); bool RecvLine(SOCKET hSocket, std::string& strLine); bool GetMyExternalIP(CNetAddr& ipRet); void AddressCurrentlyConnected(const CService& addr); CNode* FindNode(const CNetAddr& ip); CNode* FindNode(const CService& ip); CNode* ConnectNode(CAddress addrConnect, const char *strDest = NULL); void MapPort(bool fUseUPnP); unsigned short GetListenPort(); bool BindListenPort(const CService &bindAddr, std::string& strError=REF(std::string())); void StartNode(boost::thread_group& threadGroup); bool StopNode(); void SocketSendData(CNode *pnode); // Signals for message handling struct CNodeSignals { boost::signals2::signal ProcessMessages; boost::signals2::signal SendMessages; }; CNodeSignals& GetNodeSignals(); enum { LOCAL_NONE, // unknown LOCAL_IF, // address a local interface listens on LOCAL_BIND, // address explicit bound to LOCAL_UPNP, // address reported by UPnP LOCAL_HTTP, // address reported by whatismyip.com and similar LOCAL_MANUAL, // address explicitly specified (-externalip=) LOCAL_MAX }; void SetLimited(enum Network net, bool fLimited = true); bool IsLimited(enum Network net); bool IsLimited(const CNetAddr& addr); bool AddLocal(const CService& addr, int nScore = LOCAL_NONE); bool AddLocal(const CNetAddr& addr, int nScore = LOCAL_NONE); bool SeenLocal(const CService& addr); bool IsLocal(const CService& addr); bool GetLocal(CService &addr, const CNetAddr *paddrPeer = NULL); bool IsReachable(const CNetAddr &addr); void SetReachable(enum Network net, bool fFlag = true); CAddress GetLocalAddress(const CNetAddr *paddrPeer = NULL); void AddDNSandRunThread(std::string strDNS); extern bool fDiscover; extern uint64 nLocalServices; extern uint64 nLocalHostNonce; extern CAddrMan addrman; extern int nMaxConnections; extern std::vector vNodes; extern CCriticalSection cs_vNodes; extern std::map mapRelay; extern std::deque > vRelayExpiration; extern CCriticalSection cs_mapRelay; extern limitedmap mapAlreadyAskedFor; extern std::vector vAddedNodes; extern CCriticalSection cs_vAddedNodes; class CNodeStats { public: uint64 nServices; int64 nLastSend; int64 nLastRecv; int64 nTimeConnected; std::string addrName; int nVersion; std::string strSubVer; bool fInbound; int nStartingHeight; int nMisbehavior; uint64 nSendBytes; uint64 nRecvBytes; bool fSyncNode; }; class CNetMessage { public: bool in_data; // parsing header (false) or data (true) CDataStream hdrbuf; // partially received header CMessageHeader hdr; // complete header unsigned int nHdrPos; CDataStream vRecv; // received message data unsigned int nDataPos; CNetMessage(int nTypeIn, int nVersionIn) : hdrbuf(nTypeIn, nVersionIn), vRecv(nTypeIn, nVersionIn) { hdrbuf.resize(24); in_data = false; nHdrPos = 0; nDataPos = 0; } bool complete() const { if (!in_data) return false; return (hdr.nMessageSize == nDataPos); } void SetVersion(int nVersionIn) { hdrbuf.SetVersion(nVersionIn); vRecv.SetVersion(nVersionIn); } int readHeader(const char *pch, unsigned int nBytes); int readData(const char *pch, unsigned int nBytes); }; /** Information about a peer */ class CNode { public: // socket uint64 nServices; SOCKET hSocket; CDataStream ssSend; size_t nSendSize; // total size of all vSendMsg entries size_t nSendOffset; // offset inside the first vSendMsg already sent uint64 nSendBytes; std::deque vSendMsg; CCriticalSection cs_vSend; std::deque vRecvGetData; std::deque vRecvMsg; CCriticalSection cs_vRecvMsg; uint64 nRecvBytes; int nRecvVersion; int64 nLastSend; int64 nLastRecv; int64 nLastSendEmpty; int64 nTimeConnected; CAddress addr; std::string addrName; CService addrLocal; int nVersion; std::string strSubVer; bool fOneShot; bool fClient; bool fInbound; bool fNetworkNode; bool fSuccessfullyConnected; bool fDisconnect; // We use fRelayTxes for two purposes - // a) it allows us to not relay tx invs before receiving the peer's version message // b) the peer may tell us in their version message that we should not relay tx invs // until they have initialized their bloom filter. bool fRelayTxes; bool fNoDhtProxy; CSemaphoreGrant grantOutbound; CCriticalSection cs_filter; CBloomFilter* pfilter; int nRefCount; protected: // Denial-of-service detection/prevention // Key is IP address, value is banned-until-time static std::map setBanned; static CCriticalSection cs_setBanned; int nMisbehavior; public: uint256 hashContinue; CBlockIndex* pindexLastGetBlocksBegin; uint256 hashLastGetBlocksEnd; int nStartingHeight; bool fStartSync; // flood relay std::vector vAddrToSend; std::set setAddrKnown; bool fGetAddr; std::set setKnown; // inventory based relay mruset setInventoryKnown; std::vector vInventoryToSend; CCriticalSection cs_inventory; std::multimap mapAskFor; CNode(SOCKET hSocketIn, CAddress addrIn, std::string addrNameIn = "", bool fInboundIn=false) : ssSend(SER_NETWORK, MIN_PROTO_VERSION) { nServices = 0; hSocket = hSocketIn; nRecvVersion = MIN_PROTO_VERSION; nLastSend = 0; nLastRecv = 0; nSendBytes = 0; nRecvBytes = 0; nLastSendEmpty = GetTime(); nTimeConnected = GetTime(); addr = addrIn; addrName = addrNameIn == "" ? addr.ToStringIPPort() : addrNameIn; nVersion = 0; strSubVer = ""; fOneShot = false; fClient = false; // set by version message fInbound = fInboundIn; fNetworkNode = false; fSuccessfullyConnected = false; fDisconnect = false; nRefCount = 0; nSendSize = 0; nSendOffset = 0; hashContinue = 0; pindexLastGetBlocksBegin = 0; hashLastGetBlocksEnd = 0; nStartingHeight = -1; fStartSync = false; fGetAddr = false; nMisbehavior = 0; fRelayTxes = false; fNoDhtProxy = false; setInventoryKnown.max_size(SendBufferSize() / 1000); pfilter = NULL; // Be shy and don't send version until we hear if (hSocket != INVALID_SOCKET && !fInbound) PushVersion(); } ~CNode() { if (hSocket != INVALID_SOCKET) { closesocket(hSocket); hSocket = INVALID_SOCKET; } if (pfilter) delete pfilter; } private: CNode(const CNode&); void operator=(const CNode&); public: int GetRefCount() { assert(nRefCount >= 0); return nRefCount; } // requires LOCK(cs_vRecvMsg) unsigned int GetTotalRecvSize() { unsigned int total = 0; BOOST_FOREACH(const CNetMessage &msg, vRecvMsg) total += msg.vRecv.size() + 24; return total; } // requires LOCK(cs_vRecvMsg) bool ReceiveMsgBytes(const char *pch, unsigned int nBytes); // requires LOCK(cs_vRecvMsg) void SetRecvVersion(int nVersionIn) { nRecvVersion = nVersionIn; BOOST_FOREACH(CNetMessage &msg, vRecvMsg) msg.SetVersion(nVersionIn); } CNode* AddRef() { nRefCount++; return this; } void Release() { nRefCount--; } void AddAddressKnown(const CAddress& addr) { setAddrKnown.insert(addr); } void PushAddress(const CAddress& addr) { // Known checking here is only to save space from duplicates. // SendMessages will filter it again for knowns that were added // after addresses were pushed. if (addr.IsValid() && !setAddrKnown.count(addr)) vAddrToSend.push_back(addr); } void AddInventoryKnown(const CInv& inv) { { LOCK(cs_inventory); setInventoryKnown.insert(inv); } } void PushInventory(const CInv& inv) { { LOCK(cs_inventory); if (!setInventoryKnown.count(inv)) vInventoryToSend.push_back(inv); } } void AskFor(const CInv& inv) { // We're using mapAskFor as a priority queue, // the key is the earliest time the request can be sent int64 nRequestTime; limitedmap::const_iterator it = mapAlreadyAskedFor.find(inv); if (it != mapAlreadyAskedFor.end()) nRequestTime = it->second; else nRequestTime = 0; if (fDebugNet) printf("askfor %s %"PRI64d" (%s)\n", inv.ToString().c_str(), nRequestTime, DateTimeStrFormat("%H:%M:%S", nRequestTime/1000000).c_str()); // Make sure not to reuse time indexes to keep things in the same order int64 nNow = (GetTime() - 1) * 1000000; static int64 nLastTime; ++nLastTime; nNow = std::max(nNow, nLastTime); nLastTime = nNow; // Each retry is 2 minutes after the last nRequestTime = std::max(nRequestTime + 2 * 60 * 1000000, nNow); if (it != mapAlreadyAskedFor.end()) mapAlreadyAskedFor.update(it, nRequestTime); else mapAlreadyAskedFor.insert(std::make_pair(inv, nRequestTime)); mapAskFor.insert(std::make_pair(nRequestTime, inv)); } // TODO: Document the postcondition of this function. Is cs_vSend locked? void BeginMessage(const char* pszCommand) EXCLUSIVE_LOCK_FUNCTION(cs_vSend) { ENTER_CRITICAL_SECTION(cs_vSend); assert(ssSend.size() == 0); ssSend << CMessageHeader(pszCommand, 0); if (fDebug) printf("sending: %s ", pszCommand); } // TODO: Document the precondition of this function. Is cs_vSend locked? void AbortMessage() UNLOCK_FUNCTION(cs_vSend) { ssSend.clear(); LEAVE_CRITICAL_SECTION(cs_vSend); if (fDebug) printf("(aborted)\n"); } // TODO: Document the precondition of this function. Is cs_vSend locked? void EndMessage() UNLOCK_FUNCTION(cs_vSend) { if (mapArgs.count("-dropmessagestest") && GetRand(atoi(mapArgs["-dropmessagestest"])) == 0) { printf("dropmessages DROPPING SEND MESSAGE\n"); AbortMessage(); return; } if (ssSend.size() == 0) return; // Set the size unsigned int nSize = ssSend.size() - CMessageHeader::HEADER_SIZE; memcpy((char*)&ssSend[CMessageHeader::MESSAGE_SIZE_OFFSET], &nSize, sizeof(nSize)); // Set the checksum uint256 hash = Hash(ssSend.begin() + CMessageHeader::HEADER_SIZE, ssSend.end()); unsigned int nChecksum = 0; memcpy(&nChecksum, &hash, sizeof(nChecksum)); assert(ssSend.size () >= CMessageHeader::CHECKSUM_OFFSET + sizeof(nChecksum)); memcpy((char*)&ssSend[CMessageHeader::CHECKSUM_OFFSET], &nChecksum, sizeof(nChecksum)); if (fDebug) { printf("(%d bytes)\n", nSize); } std::deque::iterator it = vSendMsg.insert(vSendMsg.end(), CSerializeData()); ssSend.GetAndClear(*it); nSendSize += (*it).size(); // If write queue empty, attempt "optimistic write" if (it == vSendMsg.begin()) SocketSendData(this); LEAVE_CRITICAL_SECTION(cs_vSend); } void PushVersion(); void PushMessage(const char* pszCommand) { try { BeginMessage(pszCommand); EndMessage(); } catch (...) { AbortMessage(); throw; } } template void PushMessage(const char* pszCommand, const T1& a1) { try { BeginMessage(pszCommand); ssSend << a1; EndMessage(); } catch (...) { AbortMessage(); throw; } } template void PushMessage(const char* pszCommand, const T1& a1, const T2& a2) { try { BeginMessage(pszCommand); ssSend << a1 << a2; EndMessage(); } catch (...) { AbortMessage(); throw; } } template void PushMessage(const char* pszCommand, const T1& a1, const T2& a2, const T3& a3) { try { BeginMessage(pszCommand); ssSend << a1 << a2 << a3; EndMessage(); } catch (...) { AbortMessage(); throw; } } template void PushMessage(const char* pszCommand, const T1& a1, const T2& a2, const T3& a3, const T4& a4) { try { BeginMessage(pszCommand); ssSend << a1 << a2 << a3 << a4; EndMessage(); } catch (...) { AbortMessage(); throw; } } template void PushMessage(const char* pszCommand, const T1& a1, const T2& a2, const T3& a3, const T4& a4, const T5& a5) { try { BeginMessage(pszCommand); ssSend << a1 << a2 << a3 << a4 << a5; EndMessage(); } catch (...) { AbortMessage(); throw; } } template void PushMessage(const char* pszCommand, const T1& a1, const T2& a2, const T3& a3, const T4& a4, const T5& a5, const T6& a6) { try { BeginMessage(pszCommand); ssSend << a1 << a2 << a3 << a4 << a5 << a6; EndMessage(); } catch (...) { AbortMessage(); throw; } } template void PushMessage(const char* pszCommand, const T1& a1, const T2& a2, const T3& a3, const T4& a4, const T5& a5, const T6& a6, const T7& a7) { try { BeginMessage(pszCommand); ssSend << a1 << a2 << a3 << a4 << a5 << a6 << a7; EndMessage(); } catch (...) { AbortMessage(); throw; } } template void PushMessage(const char* pszCommand, const T1& a1, const T2& a2, const T3& a3, const T4& a4, const T5& a5, const T6& a6, const T7& a7, const T8& a8) { try { BeginMessage(pszCommand); ssSend << a1 << a2 << a3 << a4 << a5 << a6 << a7 << a8; EndMessage(); } catch (...) { AbortMessage(); throw; } } template void PushMessage(const char* pszCommand, const T1& a1, const T2& a2, const T3& a3, const T4& a4, const T5& a5, const T6& a6, const T7& a7, const T8& a8, const T9& a9) { try { BeginMessage(pszCommand); ssSend << a1 << a2 << a3 << a4 << a5 << a6 << a7 << a8 << a9; EndMessage(); } catch (...) { AbortMessage(); throw; } } bool IsSubscribed(unsigned int nChannel); void Subscribe(unsigned int nChannel, unsigned int nHops=0); void CancelSubscribe(unsigned int nChannel); void CloseSocketDisconnect(); void Cleanup(); // Denial-of-service detection/prevention // The idea is to detect peers that are behaving // badly and disconnect/ban them, but do it in a // one-coding-mistake-won't-shatter-the-entire-network // way. // IMPORTANT: There should be nothing I can give a // node that it will forward on that will make that // node's peers drop it. If there is, an attacker // can isolate a node and/or try to split the network. // Dropping a node for sending stuff that is invalid // now but might be valid in a later version is also // dangerous, because it can cause a network split // between nodes running old code and nodes running // new code. static void ClearBanned(); // needed for unit testing static bool IsBanned(CNetAddr ip); bool Misbehaving(int howmuch); // 1 == a little, 100 == a lot void copyStats(CNodeStats &stats); }; class CTransaction; void RelayTransaction(const CTransaction& tx, const uint256& txhash); void RelayTransaction(const CTransaction& tx, const uint256& txhash, const CDataStream& ss); #endif