ref: 7616b2f22d8e090dcbea817aee2cd819bc41bda7
dir: /net_dgrm.c/
#include "quakedef.h" #include <ip.h> //#define DEBUG // these two macros are to make the code more readable #define sfunc landrv[sock->landriver] #define dfunc landrv[net_landriverlevel] static int net_landriverlevel; /* statistic counters */ int packetsSent; int packetsReSent; int packetsReceived; int receivedDuplicateCount; int shortPacketCount; int droppedDatagrams; static int myDriverLevel; static uchar netbuf[4+4+NET_MAXMESSAGE]; extern int m_return_state; extern int m_state; extern qboolean m_return_onerror; extern char m_return_reason[32]; static int netpack(Addr *a, int f, uint seq, uchar *buf, int n) { hnputl(netbuf, NET_HEADERSIZE + n | f); hnputl(netbuf+4, seq); if(buf != nil) memcpy(netbuf+8, buf, n); return udpwrite(netbuf, NET_HEADERSIZE + n, a); } int Datagram_SendMessage (qsocket_t *s, sizebuf_t *data) { unsigned int n; unsigned int eom; #ifdef DEBUG if (data->cursize == 0) fatal("Datagram_SendMessage: zero length message\n"); if (data->cursize > NET_MAXMESSAGE) fatal("Datagram_SendMessage: message too big %ud\n", data->cursize); if (s->canSend == false) fatal("SendMessage: called with canSend == false\n"); #endif memcpy(s->sendMessage, data->data, data->cursize); s->sendMessageLength = data->cursize; if(data->cursize <= MAX_DATAGRAM){ n = data->cursize; eom = NFEOM; }else{ n = MAX_DATAGRAM; eom = 0; } s->canSend = false; if(netpack(&s->addr, NFDAT|eom, s->sendSequence++, s->sendMessage, n) < 0) return -1; s->lastSendTime = net_time; packetsSent++; return 1; } int SendMessageNext (qsocket_t *s) { unsigned int n; unsigned int eom; if(s->sendMessageLength <= MAX_DATAGRAM){ n = s->sendMessageLength; eom = NFEOM; }else{ n = MAX_DATAGRAM; eom = 0; } s->sendNext = false; if(netpack(&s->addr, NFDAT|eom, s->sendSequence++, s->sendMessage, n) < 0) return -1; s->lastSendTime = net_time; packetsSent++; return 1; } int ReSendMessage (qsocket_t *s) { unsigned int n; unsigned int eom; if (s->sendMessageLength <= MAX_DATAGRAM) { n = s->sendMessageLength; eom = NFEOM; } else { n = MAX_DATAGRAM; eom = 0; } s->sendNext = false; if(netpack(&s->addr, NFDAT|eom, s->sendSequence-1, s->sendMessage, n) < 0) return -1; s->lastSendTime = net_time; packetsReSent++; return 1; } qboolean Datagram_CanSendMessage (qsocket_t *sock) { if (sock->sendNext) SendMessageNext (sock); return sock->canSend; } qboolean Datagram_CanSendUnreliableMessage (qsocket_t *) { return true; } int Datagram_SendUnreliableMessage (qsocket_t *s, sizebuf_t *data) { #ifdef DEBUG if (data->cursize == 0) fatal("Datagram_SendUnreliableMessage: zero length message\n"); if (data->cursize > MAX_DATAGRAM) fatal("Datagram_SendUnreliableMessage: message too big %ud\n", data->cursize); #endif if(netpack(&s->addr, NFUNREL, s->unreliableSendSequence++, data->data, data->cursize) < 0) return -1; packetsSent++; return 1; } int Datagram_GetMessage (qsocket_t *sock) { int n; unsigned int flags; int ret = 0; unsigned int sequence; unsigned int count; if (!sock->canSend) if ((net_time - sock->lastSendTime) > 1.0) ReSendMessage (sock); while(1) { if((n = udpread(netbuf, NET_MAXMESSAGE, &sock->addr)) == 0) break; if (n == -1) { Con_Printf("Read error\n"); return -1; } if (n < NET_HEADERSIZE) { shortPacketCount++; continue; } n = nhgetl(netbuf); flags = n & (~NFMASK); n &= NFMASK; if (flags & NFCTL) continue; sequence = nhgetl(netbuf+4); packetsReceived++; if (flags & NFUNREL) { if (sequence < sock->unreliableReceiveSequence) { Con_DPrintf("Got a stale datagram\n"); ret = 0; break; } if (sequence != sock->unreliableReceiveSequence) { count = sequence - sock->unreliableReceiveSequence; droppedDatagrams += count; Con_DPrintf("Dropped %ud datagram(s)\n", count); } sock->unreliableReceiveSequence = sequence + 1; n -= NET_HEADERSIZE; SZ_Clear (&net_message); SZ_Write (&net_message, netbuf+8, n); ret = 2; break; } if (flags & NFACK) { if (sequence != (sock->sendSequence - 1)) { Con_DPrintf("Stale ACK received\n"); continue; } if (sequence == sock->ackSequence) { sock->ackSequence++; if (sock->ackSequence != sock->sendSequence) Con_DPrintf("ack sequencing error\n"); } else { Con_DPrintf("Duplicate ACK received\n"); continue; } sock->sendMessageLength -= MAX_DATAGRAM; if (sock->sendMessageLength > 0) { memcpy(sock->sendMessage, sock->sendMessage+MAX_DATAGRAM, sock->sendMessageLength); sock->sendNext = true; } else { sock->sendMessageLength = 0; sock->canSend = true; } continue; } if (flags & NFDAT) { netpack(&sock->addr, NFACK, sequence, nil, 0); if (sequence != sock->receiveSequence) { receivedDuplicateCount++; continue; } sock->receiveSequence++; n -= NET_HEADERSIZE; if (flags & NFEOM) { SZ_Clear(&net_message); SZ_Write(&net_message, sock->receiveMessage, sock->receiveMessageLength); SZ_Write(&net_message, netbuf+8, n); sock->receiveMessageLength = 0; ret = 1; break; } memcpy(sock->receiveMessage + sock->receiveMessageLength, netbuf+8, n); sock->receiveMessageLength += n; continue; } } if (sock->sendNext) SendMessageNext (sock); return ret; } void PrintStats(qsocket_t *s) { Con_Printf("canSend = %4d \n", s->canSend); Con_Printf("sendSeq = %4d ", s->sendSequence); Con_Printf("recvSeq = %4d \n", s->receiveSequence); Con_Printf("\n"); } void NET_Stats_f (void) { qsocket_t *s; if (Cmd_Argc () == 1) { Con_Printf("unreliable messages sent = %d\n", unreliableMessagesSent); Con_Printf("unreliable messages recv = %d\n", unreliableMessagesReceived); Con_Printf("reliable messages sent = %d\n", messagesSent); Con_Printf("reliable messages received = %d\n", messagesReceived); Con_Printf("packetsSent = %d\n", packetsSent); Con_Printf("packetsReSent = %d\n", packetsReSent); Con_Printf("packetsReceived = %d\n", packetsReceived); Con_Printf("receivedDuplicateCount = %d\n", receivedDuplicateCount); Con_Printf("shortPacketCount = %d\n", shortPacketCount); Con_Printf("droppedDatagrams = %d\n", droppedDatagrams); } else if(strcmp(Cmd_Argv(1), "*") == 0) { for (s = net_activeSockets; s; s = s->next) PrintStats(s); for (s = net_freeSockets; s; s = s->next) PrintStats(s); } else { for (s = net_activeSockets; s; s = s->next) if(cistrcmp(Cmd_Argv(1), s->address) == 0) break; if (s == nil) for (s = net_freeSockets; s; s = s->next) if(cistrcmp(Cmd_Argv(1), s->address) == 0) break; if (s == nil) return; PrintStats(s); } } int Datagram_Init(void) { int i; myDriverLevel = net_driverlevel; Cmd_AddCommand("net_stats", NET_Stats_f); for(i=0; i<net_numlandrivers; i++){ if(landrv[i].Init() < 0) continue; landrv[i].initialized = true; } return 0; } void Datagram_Shutdown (void) { int i; // // shutdown the lan drivers // for (i = 0; i < net_numlandrivers; i++) { if (landrv[i].initialized) { landrv[i].Shutdown (); landrv[i].initialized = false; } } } static qsocket_t *_Datagram_CheckNewConnections (void) { Addr clientaddr; int newsock; qsocket_t *sock; qsocket_t *s; int len; int command; int control; memset(&clientaddr, 0, sizeof clientaddr); if(getnewcon(&clientaddr) == 0) return nil; SZ_Clear(&net_message); len = udpread(net_message.data, net_message.maxsize, &clientaddr); if (len < sizeof(s32int)) goto done; net_message.cursize = len; MSG_BeginReading (); control = BigLong(*((int *)net_message.data)); MSG_ReadLong(); if (control == -1) goto done; if ((control & (~NFMASK)) != NFCTL) goto done; if ((control & NFMASK) != len) goto done; command = MSG_ReadByte(); if (command == CQSVINFO) { if(strcmp(MSG_ReadString(), "QUAKE") != 0) goto done; SZ_Clear(&net_message); // save space for the header, filled in later MSG_WriteLong(&net_message, 0); MSG_WriteByte(&net_message, CPSVINFO); MSG_WriteString(&net_message, dfunc.AddrToString(&myip)); MSG_WriteString(&net_message, hostname.string); MSG_WriteString(&net_message, sv.name); MSG_WriteByte(&net_message, net_activeconnections); MSG_WriteByte(&net_message, svs.maxclients); MSG_WriteByte(&net_message, NETVERSION); *((int *)net_message.data) = BigLong(NFCTL | (net_message.cursize & NFMASK)); dfunc.Write(net_message.data, net_message.cursize, &clientaddr); SZ_Clear(&net_message); goto done; } if (command == CQPLINFO) { int playerNumber; int activeNumber; int clientNumber; client_t *client; playerNumber = MSG_ReadByte(); activeNumber = -1; for (clientNumber = 0, client = svs.clients; clientNumber < svs.maxclients; clientNumber++, client++) { if (client->active) { activeNumber++; if (activeNumber == playerNumber) break; } } if (clientNumber == svs.maxclients) goto done; SZ_Clear(&net_message); // save space for the header, filled in later MSG_WriteLong(&net_message, 0); MSG_WriteByte(&net_message, CPPLINFO); MSG_WriteByte(&net_message, playerNumber); MSG_WriteString(&net_message, client->name); MSG_WriteLong(&net_message, client->colors); MSG_WriteLong(&net_message, (int)client->edict->v.frags); MSG_WriteLong(&net_message, (int)(net_time - client->netconnection->connecttime)); MSG_WriteString(&net_message, client->netconnection->address); *((int *)net_message.data) = BigLong(NFCTL | (net_message.cursize & NFMASK)); dfunc.Write(net_message.data, net_message.cursize, &clientaddr); SZ_Clear(&net_message); goto done; } if (command == CQRUINFO) { char *prevCvarName; cvar_t *var; // find the search start location prevCvarName = MSG_ReadString(); if (*prevCvarName) { var = Cvar_FindVar (prevCvarName); if (!var) goto done; var = var->next; } else var = cvar_vars; // search for the next server cvar while (var) { if (var->server) break; var = var->next; } // send the response SZ_Clear(&net_message); // save space for the header, filled in later MSG_WriteLong(&net_message, 0); MSG_WriteByte(&net_message, CPRUINFO); if (var) { MSG_WriteString(&net_message, var->name); MSG_WriteString(&net_message, var->string); } *((int *)net_message.data) = BigLong(NFCTL | (net_message.cursize & NFMASK)); dfunc.Write(net_message.data, net_message.cursize, &clientaddr); SZ_Clear(&net_message); goto done; } if (command != CQCONNECT) goto done; if(strcmp(MSG_ReadString(), "QUAKE") != 0) goto done; if (MSG_ReadByte() != NETVERSION) { SZ_Clear(&net_message); // save space for the header, filled in later MSG_WriteLong(&net_message, 0); MSG_WriteByte(&net_message, CPREJECT); MSG_WriteString(&net_message, "Incompatible version.\n"); *((int *)net_message.data) = BigLong(NFCTL | (net_message.cursize & NFMASK)); dfunc.Write(net_message.data, net_message.cursize, &clientaddr); SZ_Clear(&net_message); goto done; } // see if this guy is already connected for (s = net_activeSockets; s; s = s->next) { if (s->driver != net_driverlevel) continue; if(strcmp(clientaddr.ip, s->addr.ip) != 0 || strcmp(clientaddr.srv, s->addr.srv) != 0) continue; // is this a duplicate connection reqeust? if(strcmp(clientaddr.srv, s->addr.srv) == 0 && net_time - s->connecttime < 2.0) { // yes, so send a duplicate reply SZ_Clear(&net_message); // save space for the header, filled in later MSG_WriteLong(&net_message, 0); MSG_WriteByte(&net_message, CPACCEPT); MSG_WriteLong(&net_message, dfunc.GetSocketPort(&myip)); *((int *)net_message.data) = BigLong(NFCTL | (net_message.cursize & NFMASK)); dfunc.Write(net_message.data, net_message.cursize, &clientaddr); SZ_Clear(&net_message); goto done; } // it's somebody coming back in from a crash/disconnect // so close the old qsocket and let their retry get them back in NET_Close(s); goto done; } // allocate a QSocket sock = NET_NewQSocket (); if (sock == nil) { // no room; try to let him know SZ_Clear(&net_message); // save space for the header, filled in later MSG_WriteLong(&net_message, 0); MSG_WriteByte(&net_message, CPREJECT); MSG_WriteString(&net_message, "Server is full.\n"); *((int *)net_message.data) = BigLong(NFCTL | (net_message.cursize & NFMASK)); dfunc.Write(net_message.data, net_message.cursize, &clientaddr); SZ_Clear(&net_message); goto done; } // allocate a network socket newsock = 1; // everything is allocated, just fill in the details sock->socket = newsock; sock->landriver = net_landriverlevel; memcpy(&sock->addr, &clientaddr, sizeof clientaddr); strcpy(sock->address, UDP_AddrToString(&clientaddr)); // send him back the info about the server connection he has been allocated SZ_Clear(&net_message); // save space for the header, filled in later MSG_WriteLong(&net_message, 0); MSG_WriteByte(&net_message, CPACCEPT); MSG_WriteLong(&net_message, dfunc.GetSocketPort(&myip)); *((int *)net_message.data) = BigLong(NFCTL | (net_message.cursize & NFMASK)); dfunc.Write(net_message.data, net_message.cursize, &clientaddr); SZ_Clear(&net_message); return sock; done: close(clientaddr.fd); return nil; } qsocket_t *Datagram_CheckNewConnections (void) { qsocket_t *ret = nil; for (net_landriverlevel = 0; net_landriverlevel < net_numlandrivers; net_landriverlevel++) if (landrv[net_landriverlevel].initialized) if ((ret = _Datagram_CheckNewConnections ()) != nil) break; return ret; } static qsocket_t *_Datagram_Connect (char *host) { Addr sendaddr; Addr readaddr; qsocket_t *sock; int ret = 0; int reps; double start_time; int control; char *reason; memset(&sendaddr, 0, sizeof sendaddr); memset(&readaddr, 0, sizeof readaddr); // see if we can resolve the host name if (dfunc.getip(host, &sendaddr) == -1){ return nil; } sock = NET_NewQSocket (); if (sock == nil) goto ErrorReturn2; sock->socket = 1; sock->landriver = net_landriverlevel; // connect to the host if (dfunc.Connect(&sendaddr) == -1) goto ErrorReturn; memcpy(&readaddr, &sendaddr, sizeof readaddr); // send the connection request Con_Printf("trying...\n"); SCR_UpdateScreen (); start_time = net_time; UDP_Listen(1); for (reps = 0; reps < 3; reps++) { SZ_Clear(&net_message); // save space for the header, filled in later MSG_WriteLong(&net_message, 0); MSG_WriteByte(&net_message, CQCONNECT); MSG_WriteString(&net_message, "QUAKE"); MSG_WriteByte(&net_message, NETVERSION); *((int *)net_message.data) = BigLong(NFCTL | (net_message.cursize & NFMASK)); dfunc.Write(net_message.data, net_message.cursize, &sendaddr); SZ_Clear(&net_message); do { ret = dfunc.Read(net_message.data, net_message.maxsize, &readaddr); // if we got something, validate it if (ret > 0) { if (ret < sizeof(int)) { ret = 0; continue; } net_message.cursize = ret; MSG_BeginReading (); control = BigLong(*((int *)net_message.data)); MSG_ReadLong(); if (control == -1) { ret = 0; continue; } if ((control & (~NFMASK)) != NFCTL) { ret = 0; continue; } if ((control & NFMASK) != ret) { ret = 0; continue; } } } while (ret == 0 && (SetNetTime() - start_time) < 2.5); if (ret) break; Con_Printf("still trying...\n"); SCR_UpdateScreen (); start_time = SetNetTime(); } /* bullshit workaround for non-plan9 servers replying from different * ports. because of this workaround, multiple instances on the same * host all require different ports prior to connection. if someone * has a better solution, i'm all ears. */ start_time = SetNetTime(); do{ if(getnewcon(&sendaddr) > 0){ close(readaddr.fd); memcpy(&readaddr, &sendaddr, sizeof readaddr); break; } sleep(1); }while(SetNetTime() - start_time < 2.5); UDP_Listen(0); if (ret == 0) { reason = "No Response"; Con_Printf("%s\n", reason); strcpy(m_return_reason, reason); goto ErrorReturn; } if (ret == -1) { reason = "Network Error"; Con_Printf("%s\n", reason); strcpy(m_return_reason, reason); goto ErrorReturn; } ret = MSG_ReadByte(); if (ret == CPREJECT) { reason = MSG_ReadString(); Con_Printf(reason); strncpy(m_return_reason, reason, 31); goto ErrorReturn; } if (ret == CPACCEPT) { memcpy(&sock->addr, &readaddr, sizeof readaddr); dfunc.SetSocketPort (&sock->addr, MSG_ReadLong()); } else { reason = "Bad Response"; Con_Printf("%s\n", reason); strcpy(m_return_reason, reason); goto ErrorReturn; } strcpy(sock->address, dfunc.AddrToString(&sendaddr)); Con_Printf ("Connection accepted\n"); sock->lastMessageTime = SetNetTime(); m_return_onerror = false; return sock; ErrorReturn: close(readaddr.fd); NET_FreeQSocket(sock); ErrorReturn2: if (m_return_onerror) { key_dest = key_menu; m_state = m_return_state; m_return_onerror = false; } return nil; } qsocket_t *Datagram_Connect (char *host) { qsocket_t *ret = nil; for (net_landriverlevel = 0; net_landriverlevel < net_numlandrivers; net_landriverlevel++) if (landrv[net_landriverlevel].initialized) if ((ret = _Datagram_Connect (host)) != nil) break; return ret; } void Datagram_Close(qsocket_t *s) { close(s->addr.fd); }