/* (c) Magnus Auvinen. See licence.txt in the root of the distribution for more information. */ /* If you are missing that file, acquire a complete release at teeworlds.com. */ #include #include "config.h" #include "huffman.h" #include "network.h" const unsigned char SECURITY_TOKEN_MAGIC[4] = {'T', 'K', 'E', 'N'}; void CNetRecvUnpacker::Clear() { m_Valid = false; } void CNetRecvUnpacker::Start(const NETADDR *pAddr, CNetConnection *pConnection, int ClientID) { m_Addr = *pAddr; m_pConnection = pConnection; m_ClientID = ClientID; m_CurrentChunk = 0; m_Valid = true; } // TODO: rename this function int CNetRecvUnpacker::FetchChunk(CNetChunk *pChunk) { CNetChunkHeader Header; unsigned char *pEnd = m_Data.m_aChunkData + m_Data.m_DataSize; while(true) { unsigned char *pData = m_Data.m_aChunkData; // check for old data to unpack if(!m_Valid || m_CurrentChunk >= m_Data.m_NumChunks) { Clear(); return 0; } // TODO: add checking here so we don't read too far for(int i = 0; i < m_CurrentChunk; i++) { pData = Header.Unpack(pData, (m_pConnection && m_pConnection->m_Sixup) ? 6 : 4); pData += Header.m_Size; } // unpack the header pData = Header.Unpack(pData, (m_pConnection && m_pConnection->m_Sixup) ? 6 : 4); m_CurrentChunk++; if(pData + Header.m_Size > pEnd) { Clear(); return 0; } // handle sequence stuff if(m_pConnection && (Header.m_Flags & NET_CHUNKFLAG_VITAL)) { // anti spoof: ignore unknown sequence if(Header.m_Sequence == (m_pConnection->m_Ack + 1) % NET_MAX_SEQUENCE || m_pConnection->m_UnknownSeq) { m_pConnection->m_UnknownSeq = false; // in sequence m_pConnection->m_Ack = Header.m_Sequence; } else { // old packet that we already got if(CNetBase::IsSeqInBackroom(Header.m_Sequence, m_pConnection->m_Ack)) continue; // out of sequence, request resend if(g_Config.m_Debug) dbg_msg("conn", "asking for resend %d %d", Header.m_Sequence, (m_pConnection->m_Ack + 1) % NET_MAX_SEQUENCE); m_pConnection->SignalResend(); continue; // take the next chunk in the packet } } // fill in the info pChunk->m_ClientID = m_ClientID; pChunk->m_Address = m_Addr; pChunk->m_Flags = Header.m_Flags; pChunk->m_DataSize = Header.m_Size; pChunk->m_pData = pData; return 1; } } static const unsigned char NET_HEADER_EXTENDED[] = {'x', 'e'}; // packs the data tight and sends it void CNetBase::SendPacketConnless(NETSOCKET Socket, NETADDR *pAddr, const void *pData, int DataSize, bool Extended, unsigned char aExtra[4]) { unsigned char aBuffer[NET_MAX_PACKETSIZE]; const int DATA_OFFSET = 6; if(!Extended) { for(int i = 0; i < DATA_OFFSET; i++) aBuffer[i] = 0xff; } else { mem_copy(aBuffer, NET_HEADER_EXTENDED, sizeof(NET_HEADER_EXTENDED)); mem_copy(aBuffer + sizeof(NET_HEADER_EXTENDED), aExtra, 4); } mem_copy(aBuffer + DATA_OFFSET, pData, DataSize); net_udp_send(Socket, pAddr, aBuffer, DataSize + DATA_OFFSET); } void CNetBase::SendPacket(NETSOCKET Socket, NETADDR *pAddr, CNetPacketConstruct *pPacket, SECURITY_TOKEN SecurityToken, bool Sixup, bool NoCompress) { unsigned char aBuffer[NET_MAX_PACKETSIZE]; int CompressedSize = -1; int FinalSize = -1; // log the data if(ms_DataLogSent) { int Type = 1; io_write(ms_DataLogSent, &Type, sizeof(Type)); io_write(ms_DataLogSent, &pPacket->m_DataSize, sizeof(pPacket->m_DataSize)); io_write(ms_DataLogSent, &pPacket->m_aChunkData, pPacket->m_DataSize); io_flush(ms_DataLogSent); } int HeaderSize = NET_PACKETHEADERSIZE; if(Sixup) { HeaderSize += 4; mem_copy(&aBuffer[3], &SecurityToken, 4); } else if(SecurityToken != NET_SECURITY_TOKEN_UNSUPPORTED) { // append security token // if SecurityToken is NET_SECURITY_TOKEN_UNKNOWN we will still append it hoping to negotiate it mem_copy(&pPacket->m_aChunkData[pPacket->m_DataSize], &SecurityToken, sizeof(SecurityToken)); pPacket->m_DataSize += sizeof(SecurityToken); } // compress if(!NoCompress) CompressedSize = ms_Huffman.Compress(pPacket->m_aChunkData, pPacket->m_DataSize, &aBuffer[HeaderSize], NET_MAX_PACKETSIZE - HeaderSize); // check if the compression was enabled, successful and good enough if(!NoCompress && CompressedSize > 0 && CompressedSize < pPacket->m_DataSize) { FinalSize = CompressedSize; pPacket->m_Flags |= NET_PACKETFLAG_COMPRESSION; } else { // use uncompressed data FinalSize = pPacket->m_DataSize; mem_copy(&aBuffer[HeaderSize], pPacket->m_aChunkData, pPacket->m_DataSize); pPacket->m_Flags &= ~NET_PACKETFLAG_COMPRESSION; } if(Sixup) { unsigned Flags = 0; if(pPacket->m_Flags & NET_PACKETFLAG_CONTROL) Flags |= 1; if(pPacket->m_Flags & NET_PACKETFLAG_RESEND) Flags |= 2; if(pPacket->m_Flags & NET_PACKETFLAG_COMPRESSION) Flags |= 4; pPacket->m_Flags = Flags; } // set header and send the packet if all things are good if(FinalSize >= 0) { FinalSize += HeaderSize; aBuffer[0] = ((pPacket->m_Flags << 2) & 0xfc) | ((pPacket->m_Ack >> 8) & 0x3); aBuffer[1] = pPacket->m_Ack & 0xff; aBuffer[2] = pPacket->m_NumChunks; net_udp_send(Socket, pAddr, aBuffer, FinalSize); // log raw socket data if(ms_DataLogSent) { int Type = 0; io_write(ms_DataLogSent, &Type, sizeof(Type)); io_write(ms_DataLogSent, &FinalSize, sizeof(FinalSize)); io_write(ms_DataLogSent, aBuffer, FinalSize); io_flush(ms_DataLogSent); } } } // TODO: rename this function int CNetBase::UnpackPacket(unsigned char *pBuffer, int Size, CNetPacketConstruct *pPacket, bool &Sixup, SECURITY_TOKEN *pSecurityToken, SECURITY_TOKEN *pResponseToken) { // check the size if(Size < NET_PACKETHEADERSIZE || Size > NET_MAX_PACKETSIZE) { //dbg_msg("", "packet too small, %d", Size); return -1; } // log the data if(ms_DataLogRecv) { int Type = 0; io_write(ms_DataLogRecv, &Type, sizeof(Type)); io_write(ms_DataLogRecv, &Size, sizeof(Size)); io_write(ms_DataLogRecv, pBuffer, Size); io_flush(ms_DataLogRecv); } // read the packet pPacket->m_Flags = pBuffer[0] >> 2; if(pPacket->m_Flags & NET_PACKETFLAG_CONNLESS) { if(Size < 1) return -1; Sixup = (pBuffer[0] & 0x3) == 1; int Offset = Sixup ? 9 : 6; if(Size < Offset) return -1; if(Sixup) { mem_copy(pSecurityToken, &pBuffer[1], 4); mem_copy(pResponseToken, &pBuffer[5], 4); } pPacket->m_Flags = NET_PACKETFLAG_CONNLESS; pPacket->m_Ack = 0; pPacket->m_NumChunks = 0; pPacket->m_DataSize = Size - Offset; mem_copy(pPacket->m_aChunkData, pBuffer + Offset, pPacket->m_DataSize); if(!Sixup && mem_comp(pBuffer, NET_HEADER_EXTENDED, sizeof(NET_HEADER_EXTENDED)) == 0) { pPacket->m_Flags |= NET_PACKETFLAG_EXTENDED; mem_copy(pPacket->m_aExtraData, pBuffer + sizeof(NET_HEADER_EXTENDED), sizeof(pPacket->m_aExtraData)); } } else { if(pPacket->m_Flags & NET_PACKETFLAG_UNUSED) Sixup = true; int DataStart = Sixup ? 7 : NET_PACKETHEADERSIZE; if(Size < DataStart) return -1; pPacket->m_Ack = ((pBuffer[0] & 0x3) << 8) | pBuffer[1]; pPacket->m_NumChunks = pBuffer[2]; pPacket->m_DataSize = Size - DataStart; if(Sixup) { unsigned Flags = 0; if(pPacket->m_Flags & 1) Flags |= NET_PACKETFLAG_CONTROL; if(pPacket->m_Flags & 2) Flags |= NET_PACKETFLAG_RESEND; if(pPacket->m_Flags & 4) Flags |= NET_PACKETFLAG_COMPRESSION; pPacket->m_Flags = Flags; mem_copy(pSecurityToken, &pBuffer[3], 4); } if(pPacket->m_Flags & NET_PACKETFLAG_COMPRESSION) { // Don't allow compressed control packets. if(pPacket->m_Flags & NET_PACKETFLAG_CONTROL) { return -1; } pPacket->m_DataSize = ms_Huffman.Decompress(&pBuffer[DataStart], pPacket->m_DataSize, pPacket->m_aChunkData, sizeof(pPacket->m_aChunkData)); } else mem_copy(pPacket->m_aChunkData, &pBuffer[DataStart], pPacket->m_DataSize); } // check for errors if(pPacket->m_DataSize < 0) { if(g_Config.m_Debug) dbg_msg("network", "error during packet decoding"); return -1; } // log the data if(ms_DataLogRecv) { int Type = 1; io_write(ms_DataLogRecv, &Type, sizeof(Type)); io_write(ms_DataLogRecv, &pPacket->m_DataSize, sizeof(pPacket->m_DataSize)); io_write(ms_DataLogRecv, pPacket->m_aChunkData, pPacket->m_DataSize); io_flush(ms_DataLogRecv); } // return success return 0; } void CNetBase::SendControlMsg(NETSOCKET Socket, NETADDR *pAddr, int Ack, int ControlMsg, const void *pExtra, int ExtraSize, SECURITY_TOKEN SecurityToken, bool Sixup) { CNetPacketConstruct Construct; Construct.m_Flags = NET_PACKETFLAG_CONTROL; Construct.m_Ack = Ack; Construct.m_NumChunks = 0; Construct.m_DataSize = 1 + ExtraSize; Construct.m_aChunkData[0] = ControlMsg; if(pExtra) mem_copy(&Construct.m_aChunkData[1], pExtra, ExtraSize); // send the control message CNetBase::SendPacket(Socket, pAddr, &Construct, SecurityToken, Sixup, true); } unsigned char *CNetChunkHeader::Pack(unsigned char *pData, int Split) { pData[0] = ((m_Flags & 3) << 6) | ((m_Size >> Split) & 0x3f); pData[1] = (m_Size & ((1 << Split) - 1)); if(m_Flags & NET_CHUNKFLAG_VITAL) { pData[1] |= (m_Sequence >> 2) & (~((1 << Split) - 1)); pData[2] = m_Sequence & 0xff; return pData + 3; } return pData + 2; } unsigned char *CNetChunkHeader::Unpack(unsigned char *pData, int Split) { m_Flags = (pData[0] >> 6) & 3; m_Size = ((pData[0] & 0x3f) << Split) | (pData[1] & ((1 << Split) - 1)); m_Sequence = -1; if(m_Flags & NET_CHUNKFLAG_VITAL) { m_Sequence = ((pData[1] & (~((1 << Split) - 1))) << 2) | pData[2]; return pData + 3; } return pData + 2; } int CNetBase::IsSeqInBackroom(int Seq, int Ack) { int Bottom = (Ack - NET_MAX_SEQUENCE / 2); if(Bottom < 0) { if(Seq <= Ack) return 1; if(Seq >= (Bottom + NET_MAX_SEQUENCE)) return 1; } else { if(Seq <= Ack && Seq >= Bottom) return 1; } return 0; } IOHANDLE CNetBase::ms_DataLogSent = 0; IOHANDLE CNetBase::ms_DataLogRecv = 0; CHuffman CNetBase::ms_Huffman; void CNetBase::OpenLog(IOHANDLE DataLogSent, IOHANDLE DataLogRecv) { if(DataLogSent) { ms_DataLogSent = DataLogSent; dbg_msg("network", "logging sent packages"); } else dbg_msg("network", "failed to start logging sent packages"); if(DataLogRecv) { ms_DataLogRecv = DataLogRecv; dbg_msg("network", "logging recv packages"); } else dbg_msg("network", "failed to start logging recv packages"); } void CNetBase::CloseLog() { if(ms_DataLogSent) { dbg_msg("network", "stopped logging sent packages"); io_close(ms_DataLogSent); ms_DataLogSent = 0; } if(ms_DataLogRecv) { dbg_msg("network", "stopped logging recv packages"); io_close(ms_DataLogRecv); ms_DataLogRecv = 0; } } int CNetBase::Compress(const void *pData, int DataSize, void *pOutput, int OutputSize) { return ms_Huffman.Compress(pData, DataSize, pOutput, OutputSize); } int CNetBase::Decompress(const void *pData, int DataSize, void *pOutput, int OutputSize) { return ms_Huffman.Decompress(pData, DataSize, pOutput, OutputSize); } void CNetBase::Init() { ms_Huffman.Init(); }