net_bw.c */ // net_bw.c #include #include #include #include "quakedef.h" #include "dosisms.h" // this section is general Unix stuff that we need #define EIO 5 /* I/O error */ #define EBADS 9 #define EWOULDBLOCK 35 /* function would block */ #define EMSGSIZE 40 /* message to big for buffers */ #define EPROTONOSUPPORT 43 /* Protocol not supported */ #define ESOCKTNOSUPPORT 44 /* Socket type not supported */ #define EPFNOSUPPORT 46 /* Protocol family not supported */ #define EAFNOSUPPORT 47 /* Address family not supported */ #define ECONNABORTED 53 /* User requested hangup */ #define ENOBUFS 55 /* No buffers available */ #define EISCONN 56 /* Socket has closed */ #define ENOTCONN 57 /* Socket is not connected */ #define ESHUTDOWN 58 /* Socket is closed */ #define ETOOMANYREFS 59 /* Too many sockets open */ #define ETIMEDOUT 60 /* Connection timed out */ #define ECONNREFUSED 61 /* Connection refused */ #define AF_INET 2 /* internet */ #define PF_INET AF_INET #define SOCK_STREAM 1 /* stream */ #define SOCK_DGRAM 2 /* datagram */ #define IPPROTO_TCP 6 #define IPPROTO_UDP 17 #define INADDR_ANY 0 #define SIOCDONE 0x7300 #define FIONREAD 0x667f #define FIONBIO 0x667e #define FIONWIN 0x1000 #define FIONTIN 0x2000 #define BRDINIT 0 #define BRDADDR 10 #define MAXHOSTNAMELEN 256 #define SOL_SOCKET 0xffff /* options for socket level */ /* * Option flags per-socket. */ #define SO_DEBUG 0x0001 /* turn on debugging info recording */ #define SO_ACCEPTCONN 0x0002 /* socket has had listen() */ #define SO_REUSEADDR 0x0004 /* allow local address reuse */ #define SO_KEEPALIVE 0x0008 /* keep connections alive */ #define SO_DONTROUTE 0x0010 /* just use interface addresses */ #define SO_BROADCAST 0x0020 /* permit sending of broadcast msgs */ #define SO_USELOOPBACK 0x0040 /* bypass hardware when possible */ #define SO_LINGER 0x0080 /* linger on close if data present */ #define SO_OOBINLINE 0x0100 /* leave received OOB data in line */ #define SO_USEPRIV 0x4000 /* allocate from privileged port area */ #define SO_CANTSIG 0x8000 /* prevent SIGPIPE on SS_CANTSENDMORE */ /* * Additional options, not kept in so_options. */ #define SO_SNDBUF 0x1001 /* send buffer size */ #define SO_RCVBUF 0x1002 /* receive buffer size */ #define SO_SNDLOWAT 0x1003 /* send low-water mark */ #define SO_RCVLOWAT 0x1004 /* receive low-water mark */ #define SO_SNDTIMEO 0x1005 /* send timeout */ #define SO_RCVTIMEO 0x1006 /* receive timeout */ #define SO_ERROR 0x1007 /* get error status and clear */ #define SO_TYPE 0x1008 /* get socket type */ struct in_addr { union { struct { unsigned char s_b1,s_b2,s_b3,s_b4; } S_un_b; struct { unsigned short s_w1,s_w2; } S_un_w; unsigned long S_addr; } S_un; }; #define s_addr S_un.S_addr /* can be used for most tcp & ip code */ #define s_host S_un.S_un_b.s_b2 /* host on imp */ #define s_net S_un.S_un_b.s_b1 /* network */ #define s_imp S_un.S_un_w.s_w2 /* imp */ #define s_impno S_un.S_un_b.s_b4 /* imp # */ #define s_lh S_un.S_un_b.s_b3 /* logical host */ struct sockaddr_in { short sin_family; unsigned short sin_port; struct in_addr sin_addr; char sin_zero[8]; }; struct hostent { char *h_name; /* official name of host */ char **h_aliases; /* alias list */ int h_addrtype; /* host address type */ int h_length; /* length of address */ char **h_addr_list; /* list of addresses from name server */ #define h_addr h_addr_list[0] /* address, for backward compatiblity */ }; char *inet_ntoa(struct in_addr in); // this section is B&W specific constants & structures #define BW_IOCTL_BIND 0 #define BW_IOCTL_CLEAROPTIONS 5 #define BW_IOCTL_SETOPTIONS 6 #define BW_IOCTL_PEEK 7 #define BW_IOCTL_SETWINMASK 8 #define BW_OPTION_BLOCKING 0x01 #define BW_OPTION_REUSEBUFFERS 0x80 #define BW_ERR_USR_HANGUP 50 #define BW_ERR_HANGUP 51 #define BW_ERR_NET_ERR 52 #define BW_ERR_IS_CLOSED 53 #define BW_ERR_TIME_OUT 54 #define BW_ERR_RESET 55 #define BW_ERR_FULL 56 #define BW_ERR_BLOCK 57 #define BW_ERR_SHUTDOWN 58 #pragma pack(1) typedef struct { char state; // always 1 short localPort; struct in_addr localAddr; char reason; // always 0 char options; short dataAvailable; } BW_UDPinfo_t; typedef struct { char reserved1 [6]; unsigned short info2Offset; char reserved2 [18]; struct in_addr remoteAddr; } BW_UDPreadInfo1_t; typedef struct { short remotePort; char reserved1 [2]; unsigned short dataLenPlus8; char reserved2 [2]; char data[1]; // actual size is - 8 } BW_UDPreadInfo2_t; typedef struct { char reserved1 [2]; short remotePort; unsigned short dataLen; struct in_addr remoteAddr; char reserved2 [42]; char data[1]; // actual size is } BW_writeInfo_t; typedef struct { short ioport; byte dma; byte vector; byte irq; short bufferSize; short maxWindow; short timeZone; byte myType; int inetAddr; short value; byte subnetMask; short etherPointer; short logserverPointer; short nameserverPointer; short printserverPointer; short timeserverPointer; short gatewayPointer; short driverSegment; byte transferSize; char cardName [9]; } BW_ethdevinfo_t; #pragma pack() #define LOWMEM_SIZE 4096 static unsigned char *lowmem_buffer; static int lowmem_bufseg; static int lowmem_bufoff; static BW_ethdevinfo_t ethdevinfo; static int netmask; static struct in_addr bcastaddr; extern regs_t regs; static int net_acceptsocket = -1; // socket for fielding new connections static int net_controlsocket = 0; #include "net_bw.h" //============================================================================= static int BW_ioctl(int s, char *msg, int msglen) { Q_memcpy(lowmem_buffer, msg, msglen); regs.x.ax = 0x4403; regs.x.bx = s; regs.x.cx = msglen; regs.x.dx = lowmem_bufoff; regs.x.ds = lowmem_bufseg; if (dos_int86(0x21)) return regs.x.ax; return 0; } //============================================================================= static int BW_TranslateError(int error) { switch(error) { case BW_ERR_USR_HANGUP: return ECONNABORTED; case BW_ERR_HANGUP: return EISCONN; case BW_ERR_NET_ERR: return ENOTCONN; case BW_ERR_IS_CLOSED: return ENOTCONN; case BW_ERR_TIME_OUT: return ETIMEDOUT; case BW_ERR_RESET: return ECONNREFUSED; case BW_ERR_FULL: return ETOOMANYREFS; case BW_ERR_BLOCK: return EWOULDBLOCK; case BW_ERR_SHUTDOWN: return ESHUTDOWN; } return EIO; } //============================================================================= static int GetEthdevinfo(void) { int fd; Q_strcpy((char *)lowmem_buffer, "ETHDEV27"); regs.x.ax = 0x3d42; regs.x.ds = lowmem_bufseg; regs.x.dx = lowmem_bufoff; if (dos_int86(0x21)) return -1; fd = regs.x.ax; regs.x.ax = 0x4401; regs.x.bx = fd; regs.x.dx = 0x60; dos_int86(0x21); regs.h.ah = 0x3f; regs.x.cx = sizeof(ethdevinfo); regs.x.es = regs.x.ds = lowmem_bufseg; regs.x.dx = lowmem_bufoff; regs.x.bx = fd; if (dos_int86(0x21)) return -1; Q_memcpy(ðdevinfo, lowmem_buffer, regs.x.ax); regs.h.ah = 0x3e; regs.x.bx = fd; dos_int86(0x21); return 0; } //============================================================================= int BW_Init(void) { struct qsockaddr addr; char *colon; if (COM_CheckParm ("-noudp")) return -1; lowmem_buffer = dos_getmemory(LOWMEM_SIZE); if (!lowmem_buffer) Sys_Error("not enough low memory\n"); lowmem_bufoff = ptr2real(lowmem_buffer) & 0xf; lowmem_bufseg = ptr2real(lowmem_buffer) >> 4; if (GetEthdevinfo()) { Con_DPrintf("Beame & Whiteside TCP/IP not detected\n"); dos_freememory(lowmem_buffer); return -1; } netmask = 0xffffffff >> (32 - ethdevinfo.subnetMask); bcastaddr.s_addr = (ethdevinfo.inetAddr & netmask) | (~netmask); if ((net_controlsocket = BW_OpenSocket (0)) == -1) { dos_freememory(lowmem_buffer); Con_DPrintf ("BW_Init unable to open control socket; disabled\n"); return -1; } BW_GetSocketAddr (net_controlsocket, &addr); Q_strcpy(my_tcpip_address, BW_AddrToString (&addr)); colon = Q_strrchr (my_tcpip_address, ':'); if (colon) *colon = 0; Con_Printf("BW_Init: UDP initialized\n"); tcpipAvailable = true; return net_controlsocket; } //============================================================================= void BW_Shutdown(void) { BW_Listen (false); BW_CloseSocket (net_controlsocket); dos_freememory(lowmem_buffer); } //============================================================================= void BW_Listen (qboolean state) { // enable listening if (state) { if (net_acceptsocket != -1) return; if ((net_acceptsocket = BW_OpenSocket (net_hostport)) == -1) Sys_Error ("BW_Listen: Unable to open accept socket\n"); return; } // disable listening if (net_acceptsocket == -1) return; BW_CloseSocket (net_acceptsocket); net_acceptsocket = -1; } //============================================================================= /* OpenSocket returns a handle to a network socket that has been opened, set to nonblocking, and bound to . Additional socket options should be set here if they are needed. -1 is returned on failure. */ int BW_OpenSocket(int port) { int s; int ret; int deadman = 3 * 1024; static int dynamic = 1024; static char reuse_msg[2] = {BW_IOCTL_SETOPTIONS, BW_OPTION_REUSEBUFFERS}; static char bind_msg[3] = {BW_IOCTL_BIND, 0, 0}; static char nonblock_msg[2] = {BW_IOCTL_CLEAROPTIONS, BW_OPTION_BLOCKING}; // allocate a UDP socket Q_strcpy((char *)lowmem_buffer, "UDP-IP10"); regs.x.ax = 0x3d42; regs.x.ds = lowmem_bufseg; regs.x.dx = lowmem_bufoff; if (dos_int86(0x21)) { Con_Printf("BW_OpenSocket failed: %u\n", BW_TranslateError(regs.x.ax)); return -1; } s = regs.x.ax; // set file descriptor to raw mode regs.x.ax = 0x4401; regs.x.bx = s; regs.x.dx = 0x60; dos_int86(0x21); if (BW_ioctl(s, reuse_msg, 2)) { Con_Printf("BW_OpenSocket ioctl(reuse) failed\n"); return -1; } if (BW_ioctl(s, nonblock_msg, 2)) { Con_Printf("BW_OpenSocket ioctl(nonblocking) failed\n"); return -1; } // if a socket was specified, bind to it and return if (port) { *(short *)&bind_msg[1] = port; if (BW_ioctl(s, bind_msg, 3)) { BW_CloseSocket(s); return -1; } return s; } // B&W does NOT do dynamic allocation, so if port == 0 we must fake it do { port = dynamic++; if (dynamic == 4096) dynamic = 1024; deadman--; *(short *)&bind_msg[1] = port; ret = BW_ioctl(s, bind_msg, 3); } while (ret && deadman); if (ret) return -1; return s; } //============================================================================= int BW_CloseSocket(int socket) { regs.h.ah = 0x3e; regs.x.bx = socket; if(dos_int86(0x21)) { Con_Printf("BW_CloseSocket %u failed: %u\n", socket, BW_TranslateError(regs.x.ax)); return -1; } return 0; } //============================================================================= int BW_Connect (int socket, struct qsockaddr *hostaddr) { return 0; } //============================================================================= int BW_CheckNewConnections(void) { if (net_acceptsocket == 0) return -1; // see if there's anything waiting regs.x.ax = 0x4406; regs.x.bx = net_acceptsocket; dos_int86(0x21); if (regs.x.ax == 0) return -1; return net_acceptsocket; } //============================================================================= int BW_Read(int s, byte *buf, int len, struct qsockaddr *from) { BW_UDPreadInfo1_t *info1; BW_UDPreadInfo2_t *info2; // ask if there's anything waiting regs.x.ax = 0x4406; regs.x.bx = s; dos_int86(0x21); if (regs.x.ax == 0) return 0; // there was, so let's get it regs.h.ah = 0x3f; regs.x.cx = /* len + 53 */ LOWMEM_SIZE; regs.x.es = regs.x.ds = lowmem_bufseg; regs.x.dx = lowmem_bufoff; regs.x.bx = s; if (dos_int86(0x21)) { Con_Printf("BW UDP read error: %u\n", BW_TranslateError(regs.x.ax)); return -1; } info1 = (BW_UDPreadInfo1_t *)lowmem_buffer; info2 = (BW_UDPreadInfo2_t *)(lowmem_buffer + info1->info2Offset); if (from) { from->sa_family = AF_INET; ((struct sockaddr_in *)from)->sin_addr = info1->remoteAddr; ((struct sockaddr_in *)from)->sin_port = htons(info2->remotePort); } len = info2->dataLenPlus8 - 8; if (len > NET_DATAGRAMSIZE) { Con_Printf("BW UDP read packet too large: %u\n", len); return -1; } Q_memcpy(buf, info2->data, len); return len; } //============================================================================= int BW_Broadcast(int s, byte *msg, int len) { BW_writeInfo_t *writeInfo; // ask if we're clear to send regs.x.ax = 0x4407; regs.x.bx = s; dos_int86(0x21); if (regs.x.ax == 0) return 0; // yes, let's do it writeInfo = (BW_writeInfo_t *)lowmem_buffer; writeInfo->remoteAddr = bcastaddr; writeInfo->remotePort = net_hostport; writeInfo->dataLen = len; if (len > NET_DATAGRAMSIZE) Sys_Error("BW UDP write packet too large: %u\n", len); Q_memcpy(writeInfo->data, msg, len); writeInfo->data[len] = 0; regs.h.ah = 0x40; regs.x.bx = s; regs.x.cx = len + sizeof(BW_writeInfo_t); regs.x.es = regs.x.ds = lowmem_bufseg; regs.x.dx = lowmem_bufoff; if (dos_int86(0x21)) { Con_Printf("BW_Broadcast failed: %u\n", BW_TranslateError(regs.x.ax)); return -1; } return len; } //============================================================================= int BW_Write(int s, byte *msg, int len, struct qsockaddr *to) { BW_writeInfo_t *writeInfo; // ask if we're clear to send regs.x.ax = 0x4407; regs.x.bx = s; dos_int86(0x21); if (regs.x.ax == 0) return 0; // yes, let's do it writeInfo = (BW_writeInfo_t *)lowmem_buffer; writeInfo->remoteAddr = ((struct sockaddr_in *)to)->sin_addr; writeInfo->remotePort = ntohs(((struct sockaddr_in *)to)->sin_port); writeInfo->dataLen = len; if (len > NET_DATAGRAMSIZE) Sys_Error("BW UDP write packet too large: %u\n", len); Q_memcpy(writeInfo->data, msg, len); writeInfo->data[len] = 0; regs.h.ah = 0x40; regs.x.bx = s; regs.x.cx = len + sizeof(BW_writeInfo_t); regs.x.es = regs.x.ds = lowmem_bufseg; regs.x.dx = lowmem_bufoff; if (dos_int86(0x21)) { Con_Printf("BW_Write failed: %u\n", BW_TranslateError(regs.x.ax)); return -1; } return len; } //============================================================================= char *BW_AddrToString (struct qsockaddr *addr) { static char buffer[22]; sprintf(buffer, "%d.%d.%d.%d:%d", ((struct sockaddr_in *)addr)->sin_addr.s_net, ((struct sockaddr_in *)addr)->sin_addr.s_host, ((struct sockaddr_in *)addr)->sin_addr.s_lh, ((struct sockaddr_in *)addr)->sin_addr.s_impno, ntohs(((struct sockaddr_in *)addr)->sin_port) ); return buffer; } //============================================================================= int BW_StringToAddr (char *string, struct qsockaddr *addr) { int ha1, ha2, ha3, ha4, hp; int ipaddr; sscanf(string, "%d.%d.%d.%d:%d", &ha1, &ha2, &ha3, &ha4, &hp); ipaddr = (ha1 << 24) | (ha2 << 16) | (ha3 << 8) | ha4; addr->sa_family = AF_INET; ((struct sockaddr_in *)addr)->sin_addr.s_addr = htonl(ipaddr); ((struct sockaddr_in *)addr)->sin_port = htons((short)hp); return 0; } //============================================================================= int BW_GetSocketAddr (int socket, struct qsockaddr *addr) { regs.x.ax = 0x4402; regs.x.bx = socket; regs.x.cx = sizeof(BW_UDPinfo_t); regs.x.dx = lowmem_bufoff; regs.x.ds = lowmem_bufseg; dos_int86(0x21); addr->sa_family = AF_INET; ((struct sockaddr_in *)addr)->sin_addr.s_addr = ((BW_UDPinfo_t *)lowmem_buffer)->localAddr.s_addr; ((struct sockaddr_in *)addr)->sin_port = htons(((BW_UDPinfo_t *)lowmem_buffer)->localPort); return 0; } //============================================================================= int BW_GetNameFromAddr (struct qsockaddr *addr, char *name) { Q_strcpy(name, BW_AddrToString(addr)); return 0; } ///============================================================================= int BW_GetAddrFromName (char *name, struct qsockaddr *hostaddr) { char buff[MAXHOSTNAMELEN]; char *b; int addr; int num; int mask; int run; int port; if (name[0] < '0' || name[0] > '9') return -1; buff[0] = '.'; b = buff; Q_strcpy(buff+1, name); if (buff[1] == '.') b++; addr = 0; mask = -1; while (*b == '.') { b++; num = 0; run = 0; while (!( *b < '0' || *b > '9')) { num = num*10 + *b++ - '0'; if (++run > 3) return -1; } if ((*b < '0' || *b > '9') && *b != '.' && *b != ':' && *b != 0) return -1; if (num < 0 || num > 255) return -1; mask<<=8; addr = (addr<<8) + num; } addr = htonl(addr); mask = htonl(mask); if (*b++ == ':') port = Q_atoi(b); else port = net_hostport; hostaddr->sa_family = AF_INET; ((struct sockaddr_in *)hostaddr)->sin_port = htons((short)port); ((struct sockaddr_in *)hostaddr)->sin_addr.s_addr = ((ethdevinfo.inetAddr & mask) | addr); return 0; } //============================================================================= int BW_AddrCompare (struct qsockaddr *addr1, struct qsockaddr *addr2) { if (addr1->sa_family != addr2->sa_family) return -1; if (((struct sockaddr_in *)addr1)->sin_addr.s_addr != ((struct sockaddr_in *)addr2)->sin_addr.s_addr) return -1; if (((struct sockaddr_in *)addr1)->sin_port != ((struct sockaddr_in *)addr2)->sin_port) return 1; return 0; } //============================================================================= int BW_GetSocketPort (struct qsockaddr *addr) { return ntohs(((struct sockaddr_in *)addr)->sin_port); } int BW_SetSocketPort (struct qsockaddr *addr, int port) { ((struct sockaddr_in *)addr)->sin_port = htons(port); return 0; } //=============================================================================