/* * Copyright (c) 2002, Oracle and/or its affiliates. All rights reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. */ /* Copyright 1993, 1994, 1998 The Open Group Permission to use, copy, modify, distribute, and sell this software and its documentation for any purpose is hereby granted without fee, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation. The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE OPEN GROUP BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. Except as contained in this notice, the name of the copyright holders shall not be used in advertising or otherwise to promote the sale, use or other dealings in this Software without prior written authorization from the copyright holders. * Copyright 1993, 1994 NCR Corporation - Dayton, Ohio, USA * * All Rights Reserved * * Permission to use, copy, modify, and distribute this software and its * documentation for any purpose and without fee is hereby granted, provided * that the above copyright notice appear in all copies and that both that * copyright notice and this permission notice appear in supporting * documentation, and that the name NCR not be used in advertising * or publicity pertaining to distribution of the software without specific, * written prior permission. NCR makes no representations about the * suitability of this software for any purpose. It is provided "as is" * without express or implied warranty. * * NCR DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, * INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN * NO EVENT SHALL NCR BE LIABLE FOR ANY SPECIAL, INDIRECT OR * CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS * OF USE, DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, * NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN * CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #ifdef XTHREADS #include #endif #ifndef WIN32 #if defined(TCPCONN) || defined(UNIXCONN) #include #include #include #endif #if defined(TCPCONN) || defined(UNIXCONN) #define X_INCLUDE_NETDB_H #define XOS_USE_NO_LOCKING #include #endif #ifdef UNIXCONN #ifndef X_NO_SYS_UN #include #endif #include #endif #ifndef NO_TCP_H #if defined(linux) || defined(__GLIBC__) #include #endif /* osf */ #if defined(__NetBSD__) || defined(__OpenBSD__) || defined(__FreeBSD__) || defined(__DragonFly__) #include #include #endif /* __NetBSD__ || __OpenBSD__ || __FreeBSD__ || __DragonFly__ */ #include #endif /* !NO_TCP_H */ #include #if defined(SVR4) || defined(__SVR4) #include #endif #if (defined(__i386__) && defined(SYSV)) && !defined(SCO325) && !defined(sun) #include #endif #if defined(__i386__) && defined(SYSV) #include #endif #include #else /* !WIN32 */ #include #include #include #undef close #define close closesocket #undef ECONNREFUSED #define ECONNREFUSED WSAECONNREFUSED #undef EADDRINUSE #define EADDRINUSE WSAEADDRINUSE #undef EPROTOTYPE #define EPROTOTYPE WSAEPROTOTYPE #undef EWOULDBLOCK #define EWOULDBLOCK WSAEWOULDBLOCK #undef EINPROGRESS #define EINPROGRESS WSAEINPROGRESS #undef EINTR #define EINTR WSAEINTR #define X_INCLUDE_NETDB_H #define XOS_USE_MTSAFE_NETDBAPI #include #endif /* WIN32 */ #if defined(SO_DONTLINGER) && defined(SO_LINGER) #undef SO_DONTLINGER #endif /* others don't need this */ #define SocketInitOnce() /**/ #ifdef linux #define HAVE_ABSTRACT_SOCKETS #endif #define MIN_BACKLOG 128 #ifdef SOMAXCONN #if SOMAXCONN > MIN_BACKLOG #define BACKLOG SOMAXCONN #endif #endif #ifndef BACKLOG #define BACKLOG MIN_BACKLOG #endif /* * This is the Socket implementation of the X Transport service layer * * This file contains the implementation for both the UNIX and INET domains, * and can be built for either one, or both. * */ typedef struct _Sockettrans2dev { const char *transname; int family; int devcotsname; int devcltsname; int protocol; } Sockettrans2dev; static Sockettrans2dev Sockettrans2devtab[] = { #ifdef TCPCONN {"inet",AF_INET,SOCK_STREAM,SOCK_DGRAM,0}, #if !defined(IPv6) || !defined(AF_INET6) {"tcp",AF_INET,SOCK_STREAM,SOCK_DGRAM,0}, #else /* IPv6 */ {"tcp",AF_INET6,SOCK_STREAM,SOCK_DGRAM,0}, {"tcp",AF_INET,SOCK_STREAM,SOCK_DGRAM,0}, /* fallback */ {"inet6",AF_INET6,SOCK_STREAM,SOCK_DGRAM,0}, #endif #endif /* TCPCONN */ #ifdef UNIXCONN {"unix",AF_UNIX,SOCK_STREAM,SOCK_DGRAM,0}, #if !defined(LOCALCONN) {"local",AF_UNIX,SOCK_STREAM,SOCK_DGRAM,0}, #endif /* !LOCALCONN */ #endif /* UNIXCONN */ }; #define NUMSOCKETFAMILIES (sizeof(Sockettrans2devtab)/sizeof(Sockettrans2dev)) #ifdef TCPCONN static int TRANS(SocketINETClose) (XtransConnInfo ciptr); #endif #ifdef UNIXCONN #if defined(X11_t) #define UNIX_PATH "/tmp/.X11-unix/X" #define UNIX_DIR "/tmp/.X11-unix" #endif /* X11_t */ #if defined(XIM_t) #define UNIX_PATH "/tmp/.XIM-unix/XIM" #define UNIX_DIR "/tmp/.XIM-unix" #endif /* XIM_t */ #if defined(FS_t) || defined(FONT_t) #define UNIX_PATH "/tmp/.font-unix/fs" #define UNIX_DIR "/tmp/.font-unix" #endif /* FS_t || FONT_t */ #if defined(ICE_t) #define UNIX_PATH "/tmp/.ICE-unix/" #define UNIX_DIR "/tmp/.ICE-unix" #endif /* ICE_t */ #if defined(TEST_t) #define UNIX_PATH "/tmp/.Test-unix/test" #define UNIX_DIR "/tmp/.Test-unix" #endif #if defined(LBXPROXY_t) #define UNIX_PATH "/tmp/.X11-unix/X" #define UNIX_DIR "/tmp/.X11-unix" #endif #endif /* UNIXCONN */ #define PORTBUFSIZE 32 #ifndef MAXHOSTNAMELEN #define MAXHOSTNAMELEN 255 #endif #if defined HAVE_SOCKLEN_T || (defined(IPv6) && defined(AF_INET6)) #ifdef _MSC_VER # define SOCKLEN_T int #else # define SOCKLEN_T socklen_t #endif #elif defined(SVR4) || defined(__SVR4) || defined(__SCO__) # define SOCKLEN_T size_t #else # define SOCKLEN_T int #endif static int TRANS(SocketRecvFdInvalid)(XtransConnInfo ciptr); static int TRANS(SocketSendFdInvalid)(XtransConnInfo ciptr, int fd, int do_close); /* * These are some utility function used by the real interface function below. */ static int TRANS(SocketSelectFamily) (int first, const char *family) { int i; prmsg (3,"SocketSelectFamily(%s)\n", family); for (i = first + 1; i < NUMSOCKETFAMILIES;i++) { if (!strcmp (family, Sockettrans2devtab[i].transname)) return i; } return (first == -1 ? -2 : -1); } /* * This function gets the local address of the socket and stores it in the * XtransConnInfo structure for the connection. */ static int TRANS(SocketINETGetAddr) (XtransConnInfo ciptr) { #if defined(IPv6) && defined(AF_INET6) struct sockaddr_storage socknamev6; #else struct sockaddr_in socknamev4; #endif void *socknamePtr; SOCKLEN_T namelen; prmsg (3,"SocketINETGetAddr(%p)\n", ciptr); #if defined(IPv6) && defined(AF_INET6) namelen = sizeof(socknamev6); socknamePtr = &socknamev6; #else namelen = sizeof(socknamev4); socknamePtr = &socknamev4; #endif bzero(socknamePtr, namelen); if (getsockname (ciptr->fd,(struct sockaddr *) socknamePtr, (void *)&namelen) < 0) { #ifdef WIN32 errno = WSAGetLastError(); #endif prmsg (1,"SocketINETGetAddr: getsockname() failed: %d\n", EGET()); return -1; } /* * Everything looks good: fill in the XtransConnInfo structure. */ if ((ciptr->addr = malloc (namelen)) == NULL) { prmsg (1, "SocketINETGetAddr: Can't allocate space for the addr\n"); return -1; } #if defined(IPv6) && defined(AF_INET6) ciptr->family = ((struct sockaddr *)socknamePtr)->sa_family; #else ciptr->family = socknamev4.sin_family; #endif ciptr->addrlen = namelen; memcpy (ciptr->addr, socknamePtr, ciptr->addrlen); return 0; } /* * This function gets the remote address of the socket and stores it in the * XtransConnInfo structure for the connection. */ static int TRANS(SocketINETGetPeerAddr) (XtransConnInfo ciptr) { #if defined(IPv6) && defined(AF_INET6) struct sockaddr_storage socknamev6; #endif struct sockaddr_in socknamev4; void *socknamePtr; SOCKLEN_T namelen; #if defined(IPv6) && defined(AF_INET6) if (ciptr->family == AF_INET6) { namelen = sizeof(socknamev6); socknamePtr = &socknamev6; } else #endif { namelen = sizeof(socknamev4); socknamePtr = &socknamev4; } bzero(socknamePtr, namelen); prmsg (3,"SocketINETGetPeerAddr(%p)\n", ciptr); if (getpeername (ciptr->fd, (struct sockaddr *) socknamePtr, (void *)&namelen) < 0) { #ifdef WIN32 errno = WSAGetLastError(); #endif prmsg (1,"SocketINETGetPeerAddr: getpeername() failed: %d\n", EGET()); return -1; } /* * Everything looks good: fill in the XtransConnInfo structure. */ if ((ciptr->peeraddr = malloc (namelen)) == NULL) { prmsg (1, "SocketINETGetPeerAddr: Can't allocate space for the addr\n"); return -1; } ciptr->peeraddrlen = namelen; memcpy (ciptr->peeraddr, socknamePtr, ciptr->peeraddrlen); return 0; } static XtransConnInfo TRANS(SocketOpen) (int i, int type) { XtransConnInfo ciptr; prmsg (3,"SocketOpen(%d,%d)\n", i, type); if ((ciptr = calloc (1, sizeof(struct _XtransConnInfo))) == NULL) { prmsg (1, "SocketOpen: malloc failed\n"); return NULL; } if ((ciptr->fd = socket(Sockettrans2devtab[i].family, type, Sockettrans2devtab[i].protocol)) < 0 #ifndef WIN32 #if (defined(X11_t) && !defined(USE_POLL)) || defined(FS_t) || defined(FONT_t) || ciptr->fd >= sysconf(_SC_OPEN_MAX) #endif #endif ) { #ifdef WIN32 errno = WSAGetLastError(); #endif prmsg (2, "SocketOpen: socket() failed for %s\n", Sockettrans2devtab[i].transname); free (ciptr); return NULL; } #ifdef TCP_NODELAY if (Sockettrans2devtab[i].family == AF_INET #if defined(IPv6) && defined(AF_INET6) || Sockettrans2devtab[i].family == AF_INET6 #endif ) { /* * turn off TCP coalescence for INET sockets */ int tmp = 1; setsockopt (ciptr->fd, IPPROTO_TCP, TCP_NODELAY, (char *) &tmp, sizeof (int)); } #endif return ciptr; } #ifdef TRANS_REOPEN static XtransConnInfo TRANS(SocketReopen) (int i _X_UNUSED, int type, int fd, char *port) { XtransConnInfo ciptr; int portlen; struct sockaddr *addr; size_t addrlen; prmsg (3,"SocketReopen(%d,%d,%s)\n", type, fd, port); if (port == NULL) { prmsg (1, "SocketReopen: port was null!\n"); return NULL; } portlen = strlen(port) + 1; // include space for trailing null #ifdef SOCK_MAXADDRLEN if (portlen < 0 || portlen > (SOCK_MAXADDRLEN + 2)) { prmsg (1, "SocketReopen: invalid portlen %d\n", portlen); return NULL; } if (portlen < 14) portlen = 14; #else if (portlen < 0 || portlen > 14) { prmsg (1, "SocketReopen: invalid portlen %d\n", portlen); return NULL; } #endif /*SOCK_MAXADDRLEN*/ if ((ciptr = calloc (1, sizeof(struct _XtransConnInfo))) == NULL) { prmsg (1, "SocketReopen: malloc(ciptr) failed\n"); return NULL; } ciptr->fd = fd; addrlen = portlen + offsetof(struct sockaddr, sa_data); if ((addr = calloc (1, addrlen)) == NULL) { prmsg (1, "SocketReopen: malloc(addr) failed\n"); free (ciptr); return NULL; } ciptr->addr = (char *) addr; ciptr->addrlen = addrlen; if ((ciptr->peeraddr = calloc (1, addrlen)) == NULL) { prmsg (1, "SocketReopen: malloc(portaddr) failed\n"); free (addr); free (ciptr); return NULL; } ciptr->peeraddrlen = addrlen; /* Initialize ciptr structure as if it were a normally-opened unix socket */ ciptr->flags = TRANS_LOCAL | TRANS_NOUNLINK; #ifdef BSD44SOCKETS addr->sa_len = addrlen; #endif addr->sa_family = AF_UNIX; #ifdef HAS_STRLCPY strlcpy(addr->sa_data, port, portlen); #else strncpy(addr->sa_data, port, portlen); #endif ciptr->family = AF_UNIX; memcpy(ciptr->peeraddr, ciptr->addr, addrlen); ciptr->port = rindex(addr->sa_data, ':'); if (ciptr->port == NULL) { if (is_numeric(addr->sa_data)) { ciptr->port = addr->sa_data; } } else if (ciptr->port[0] == ':') { ciptr->port++; } /* port should now point to portnum or NULL */ return ciptr; } #endif /* TRANS_REOPEN */ /* * These functions are the interface supplied in the Xtransport structure */ #ifdef TRANS_CLIENT static XtransConnInfo TRANS(SocketOpenCOTSClientBase) (const char *transname, const char *protocol, const char *host, const char *port, int previndex) { XtransConnInfo ciptr; int i = previndex; prmsg (2, "SocketOpenCOTSClient(%s,%s,%s)\n", protocol, host, port); SocketInitOnce(); while ((i = TRANS(SocketSelectFamily) (i, transname)) >= 0) { if ((ciptr = TRANS(SocketOpen) ( i, Sockettrans2devtab[i].devcotsname)) != NULL) { /* Save the index for later use */ ciptr->index = i; break; } } if (i < 0) { if (i == -1) prmsg (1,"SocketOpenCOTSClient: Unable to open socket for %s\n", transname); else prmsg (1,"SocketOpenCOTSClient: Unable to determine socket type for %s\n", transname); return NULL; } return ciptr; } static XtransConnInfo TRANS(SocketOpenCOTSClient) (Xtransport *thistrans, char *protocol, char *host, char *port) { return TRANS(SocketOpenCOTSClientBase)( thistrans->TransName, protocol, host, port, -1); } #endif /* TRANS_CLIENT */ #ifdef TRANS_SERVER static XtransConnInfo TRANS(SocketOpenCOTSServer) (Xtransport *thistrans, char *protocol, char *host, char *port) { XtransConnInfo ciptr; int i = -1; prmsg (2,"SocketOpenCOTSServer(%s,%s,%s)\n", protocol, host, port); SocketInitOnce(); while ((i = TRANS(SocketSelectFamily) (i, thistrans->TransName)) >= 0) { if ((ciptr = TRANS(SocketOpen) ( i, Sockettrans2devtab[i].devcotsname)) != NULL) break; } if (i < 0) { if (i == -1) prmsg (1,"SocketOpenCOTSServer: Unable to open socket for %s\n", thistrans->TransName); else prmsg (1,"SocketOpenCOTSServer: Unable to determine socket type for %s\n", thistrans->TransName); return NULL; } /* * Using this prevents the bind() check for an existing server listening * on the same port, but it is required for other reasons. */ #ifdef SO_REUSEADDR /* * SO_REUSEADDR only applied to AF_INET && AF_INET6 */ if (Sockettrans2devtab[i].family == AF_INET #if defined(IPv6) && defined(AF_INET6) || Sockettrans2devtab[i].family == AF_INET6 #endif ) { int one = 1; setsockopt (ciptr->fd, SOL_SOCKET, SO_REUSEADDR, (char *) &one, sizeof (int)); } #endif #ifdef IPV6_V6ONLY if (Sockettrans2devtab[i].family == AF_INET6) { int one = 1; setsockopt(ciptr->fd, IPPROTO_IPV6, IPV6_V6ONLY, (const char *)&one, sizeof(int)); } #endif /* Save the index for later use */ ciptr->index = i; return ciptr; } #endif /* TRANS_SERVER */ #ifdef TRANS_CLIENT static XtransConnInfo TRANS(SocketOpenCLTSClient) (Xtransport *thistrans, char *protocol, char *host, char *port) { XtransConnInfo ciptr; int i = -1; prmsg (2,"SocketOpenCLTSClient(%s,%s,%s)\n", protocol, host, port); SocketInitOnce(); while ((i = TRANS(SocketSelectFamily) (i, thistrans->TransName)) >= 0) { if ((ciptr = TRANS(SocketOpen) ( i, Sockettrans2devtab[i].devcotsname)) != NULL) break; } if (i < 0) { if (i == -1) prmsg (1,"SocketOpenCLTSClient: Unable to open socket for %s\n", thistrans->TransName); else prmsg (1,"SocketOpenCLTSClient: Unable to determine socket type for %s\n", thistrans->TransName); return NULL; } /* Save the index for later use */ ciptr->index = i; return ciptr; } #endif /* TRANS_CLIENT */ #ifdef TRANS_SERVER static XtransConnInfo TRANS(SocketOpenCLTSServer) (Xtransport *thistrans, char *protocol, char *host, char *port) { XtransConnInfo ciptr; int i = -1; prmsg (2,"SocketOpenCLTSServer(%s,%s,%s)\n", protocol, host, port); SocketInitOnce(); while ((i = TRANS(SocketSelectFamily) (i, thistrans->TransName)) >= 0) { if ((ciptr = TRANS(SocketOpen) ( i, Sockettrans2devtab[i].devcotsname)) != NULL) break; } if (i < 0) { if (i == -1) prmsg (1,"SocketOpenCLTSServer: Unable to open socket for %s\n", thistrans->TransName); else prmsg (1,"SocketOpenCLTSServer: Unable to determine socket type for %s\n", thistrans->TransName); return NULL; } #ifdef IPV6_V6ONLY if (Sockettrans2devtab[i].family == AF_INET6) { int one = 1; setsockopt(ciptr->fd, IPPROTO_IPV6, IPV6_V6ONLY, (const char *)&one, sizeof(int)); } #endif /* Save the index for later use */ ciptr->index = i; return ciptr; } #endif /* TRANS_SERVER */ #ifdef TRANS_REOPEN static XtransConnInfo TRANS(SocketReopenCOTSServer) (Xtransport *thistrans, int fd, char *port) { XtransConnInfo ciptr; int i = -1; prmsg (2, "SocketReopenCOTSServer(%d, %s)\n", fd, port); SocketInitOnce(); while ((i = TRANS(SocketSelectFamily) (i, thistrans->TransName)) >= 0) { if ((ciptr = TRANS(SocketReopen) ( i, Sockettrans2devtab[i].devcotsname, fd, port)) != NULL) break; } if (i < 0) { if (i == -1) prmsg (1,"SocketReopenCOTSServer: Unable to open socket for %s\n", thistrans->TransName); else prmsg (1,"SocketReopenCOTSServer: Unable to determine socket type for %s\n", thistrans->TransName); return NULL; } /* Save the index for later use */ ciptr->index = i; return ciptr; } static XtransConnInfo TRANS(SocketReopenCLTSServer) (Xtransport *thistrans, int fd, char *port) { XtransConnInfo ciptr; int i = -1; prmsg (2, "SocketReopenCLTSServer(%d, %s)\n", fd, port); SocketInitOnce(); while ((i = TRANS(SocketSelectFamily) (i, thistrans->TransName)) >= 0) { if ((ciptr = TRANS(SocketReopen) ( i, Sockettrans2devtab[i].devcotsname, fd, port)) != NULL) break; } if (i < 0) { if (i == -1) prmsg (1,"SocketReopenCLTSServer: Unable to open socket for %s\n", thistrans->TransName); else prmsg (1,"SocketReopenCLTSServer: Unable to determine socket type for %s\n", thistrans->TransName); return NULL; } /* Save the index for later use */ ciptr->index = i; return ciptr; } #endif /* TRANS_REOPEN */ static int TRANS(SocketSetOption) (XtransConnInfo ciptr, int option, int arg) { prmsg (2,"SocketSetOption(%d,%d,%d)\n", ciptr->fd, option, arg); return -1; } #ifdef UNIXCONN static int set_sun_path(const char *port, const char *upath, char *path, int abstract) { struct sockaddr_un s; int maxlen = sizeof(s.sun_path) - 1; const char *at = ""; if (!port || !*port || !path) return -1; #ifdef HAVE_ABSTRACT_SOCKETS if (port[0] == '@') upath = ""; else if (abstract) at = "@"; #endif if (*port == '/') /* a full pathname */ upath = ""; if (strlen(port) + strlen(upath) > maxlen) return -1; snprintf(path, sizeof(s.sun_path), "%s%s%s", at, upath, port); return 0; } #endif #ifdef TRANS_SERVER #ifndef SO_BINDRETRYCOUNT #define SO_BINDRETRYCOUNT 20 #endif static int TRANS(SocketCreateListener) (XtransConnInfo ciptr, struct sockaddr *sockname, int socknamelen, unsigned int flags) { SOCKLEN_T namelen = socknamelen; int fd = ciptr->fd; int retry; prmsg (3, "SocketCreateListener(%p,%d)\n", ciptr, fd); if (Sockettrans2devtab[ciptr->index].family == AF_INET #if defined(IPv6) && defined(AF_INET6) || Sockettrans2devtab[ciptr->index].family == AF_INET6 #endif ) retry = SO_BINDRETRYCOUNT; else retry = 0; while (bind (fd, (struct sockaddr *) sockname, namelen) < 0) { if (errno == EADDRINUSE) { if (flags & ADDR_IN_USE_ALLOWED) break; else return TRANS_ADDR_IN_USE; } if (retry-- == 0) { prmsg (1, "SocketCreateListener: failed to bind listener\n"); close (fd); return TRANS_CREATE_LISTENER_FAILED; } #ifdef SO_REUSEADDR sleep (1); #else sleep (10); #endif /* SO_REUSEDADDR */ } if (Sockettrans2devtab[ciptr->index].family == AF_INET #if defined(IPv6) && defined(AF_INET6) || Sockettrans2devtab[ciptr->index].family == AF_INET6 #endif ) { #ifdef SO_DONTLINGER setsockopt (fd, SOL_SOCKET, SO_DONTLINGER, (char *) NULL, 0); #else #ifdef SO_LINGER { static int linger[2] = { 0, 0 }; setsockopt (fd, SOL_SOCKET, SO_LINGER, (char *) linger, sizeof (linger)); } #endif #endif } if (listen (fd, BACKLOG) < 0) { prmsg (1, "SocketCreateListener: listen() failed\n"); close (fd); return TRANS_CREATE_LISTENER_FAILED; } /* Set a flag to indicate that this connection is a listener */ ciptr->flags = 1 | (ciptr->flags & TRANS_KEEPFLAGS); return 0; } #ifdef TCPCONN static int TRANS(SocketINETCreateListener) (XtransConnInfo ciptr, char *port, unsigned int flags) { #if defined(IPv6) && defined(AF_INET6) struct sockaddr_storage sockname; #else struct sockaddr_in sockname; #endif unsigned short sport; SOCKLEN_T namelen = sizeof(sockname); int status; long tmpport; #ifdef XTHREADS_NEEDS_BYNAMEPARAMS _Xgetservbynameparams sparams; #endif struct servent *servp; #ifdef X11_t char portbuf[PORTBUFSIZE]; #endif prmsg (2, "SocketINETCreateListener(%s)\n", port); #ifdef X11_t /* * X has a well known port, that is transport dependent. It is easier * to handle it here, than try and come up with a transport independent * representation that can be passed in and resolved the usual way. * * The port that is passed here is really a string containing the idisplay * from ConnectDisplay(). */ if (is_numeric (port)) { /* fixup the server port address */ tmpport = X_TCP_PORT + strtol (port, (char**)NULL, 10); snprintf (portbuf, sizeof(portbuf), "%lu", tmpport); port = portbuf; } #endif if (port && *port) { /* Check to see if the port string is just a number (handles X11) */ if (!is_numeric (port)) { if ((servp = _XGetservbyname (port,"tcp",sparams)) == NULL) { prmsg (1, "SocketINETCreateListener: Unable to get service for %s\n", port); return TRANS_CREATE_LISTENER_FAILED; } /* we trust getservbyname to return a valid number */ sport = servp->s_port; } else { tmpport = strtol (port, (char**)NULL, 10); /* * check that somehow the port address isn't negative or in * the range of reserved port addresses. This can happen and * be very bad if the server is suid-root and the user does * something (dumb) like `X :60049`. */ if (tmpport < 1024 || tmpport > USHRT_MAX) return TRANS_CREATE_LISTENER_FAILED; sport = (unsigned short) tmpport; } } else sport = 0; bzero(&sockname, sizeof(sockname)); #if defined(IPv6) && defined(AF_INET6) if (Sockettrans2devtab[ciptr->index].family == AF_INET) { namelen = sizeof (struct sockaddr_in); #ifdef BSD44SOCKETS ((struct sockaddr_in *)&sockname)->sin_len = namelen; #endif ((struct sockaddr_in *)&sockname)->sin_family = AF_INET; ((struct sockaddr_in *)&sockname)->sin_port = htons(sport); ((struct sockaddr_in *)&sockname)->sin_addr.s_addr = htonl(INADDR_ANY); } else { namelen = sizeof (struct sockaddr_in6); #ifdef SIN6_LEN ((struct sockaddr_in6 *)&sockname)->sin6_len = sizeof(sockname); #endif ((struct sockaddr_in6 *)&sockname)->sin6_family = AF_INET6; ((struct sockaddr_in6 *)&sockname)->sin6_port = htons(sport); ((struct sockaddr_in6 *)&sockname)->sin6_addr = in6addr_any; } #else #ifdef BSD44SOCKETS sockname.sin_len = sizeof (sockname); #endif sockname.sin_family = AF_INET; sockname.sin_port = htons (sport); sockname.sin_addr.s_addr = htonl (INADDR_ANY); #endif if ((status = TRANS(SocketCreateListener) (ciptr, (struct sockaddr *) &sockname, namelen, flags)) < 0) { prmsg (1, "SocketINETCreateListener: ...SocketCreateListener() failed\n"); return status; } if (TRANS(SocketINETGetAddr) (ciptr) < 0) { prmsg (1, "SocketINETCreateListener: ...SocketINETGetAddr() failed\n"); return TRANS_CREATE_LISTENER_FAILED; } return 0; } #endif /* TCPCONN */ #ifdef UNIXCONN static int TRANS(SocketUNIXCreateListener) (XtransConnInfo ciptr, char *port, unsigned int flags) { struct sockaddr_un sockname; int namelen; int oldUmask; int status; unsigned int mode; char tmpport[108]; int abstract = 0; #ifdef HAVE_ABSTRACT_SOCKETS abstract = ciptr->transptr->flags & TRANS_ABSTRACT; #endif prmsg (2, "SocketUNIXCreateListener(%s)\n", port ? port : "NULL"); /* Make sure the directory is created */ oldUmask = umask (0); #ifdef UNIX_DIR #ifdef HAS_STICKY_DIR_BIT mode = 01777; #else mode = 0777; #endif if (!abstract && trans_mkdir(UNIX_DIR, mode) == -1) { prmsg (1, "SocketUNIXCreateListener: mkdir(%s) failed, errno = %d\n", UNIX_DIR, errno); (void) umask (oldUmask); return TRANS_CREATE_LISTENER_FAILED; } #endif memset(&sockname, 0, sizeof(sockname)); sockname.sun_family = AF_UNIX; if (!(port && *port)) { snprintf (tmpport, sizeof(tmpport), "%s%ld", UNIX_PATH, (long)getpid()); port = tmpport; } if (set_sun_path(port, UNIX_PATH, sockname.sun_path, abstract) != 0) { prmsg (1, "SocketUNIXCreateListener: path too long\n"); return TRANS_CREATE_LISTENER_FAILED; } #if (defined(BSD44SOCKETS) || defined(__UNIXWARE__)) sockname.sun_len = strlen(sockname.sun_path); #endif #if defined(BSD44SOCKETS) || defined(SUN_LEN) namelen = SUN_LEN(&sockname); #else namelen = strlen(sockname.sun_path) + offsetof(struct sockaddr_un, sun_path); #endif if (abstract) { sockname.sun_path[0] = '\0'; namelen = offsetof(struct sockaddr_un, sun_path) + 1 + strlen(&sockname.sun_path[1]); } else unlink (sockname.sun_path); if ((status = TRANS(SocketCreateListener) (ciptr, (struct sockaddr *) &sockname, namelen, flags)) < 0) { prmsg (1, "SocketUNIXCreateListener: ...SocketCreateListener() failed\n"); (void) umask (oldUmask); return status; } /* * Now that the listener is esablished, create the addr info for * this connection. getpeername() doesn't work for UNIX Domain Sockets * on some systems (hpux at least), so we will just do it manually, instead * of calling something like TRANS(SocketUNIXGetAddr). */ namelen = sizeof (sockname); /* this will always make it the same size */ if ((ciptr->addr = malloc (namelen)) == NULL) { prmsg (1, "SocketUNIXCreateListener: Can't allocate space for the addr\n"); (void) umask (oldUmask); return TRANS_CREATE_LISTENER_FAILED; } if (abstract) sockname.sun_path[0] = '@'; ciptr->family = sockname.sun_family; ciptr->addrlen = namelen; memcpy (ciptr->addr, &sockname, ciptr->addrlen); (void) umask (oldUmask); return 0; } static int TRANS(SocketUNIXResetListener) (XtransConnInfo ciptr) { /* * See if the unix domain socket has disappeared. If it has, recreate it. */ struct sockaddr_un *unsock = (struct sockaddr_un *) ciptr->addr; struct stat statb; int status = TRANS_RESET_NOOP; unsigned int mode; int abstract = 0; #ifdef HAVE_ABSTRACT_SOCKETS abstract = ciptr->transptr->flags & TRANS_ABSTRACT; #endif prmsg (3, "SocketUNIXResetListener(%p,%d)\n", ciptr, ciptr->fd); if (!abstract && ( stat (unsock->sun_path, &statb) == -1 || ((statb.st_mode & S_IFMT) != #if defined(NCR) || defined(SCO325) || !defined(S_IFSOCK) S_IFIFO #else S_IFSOCK #endif ))) { int oldUmask = umask (0); #ifdef UNIX_DIR #ifdef HAS_STICKY_DIR_BIT mode = 01777; #else mode = 0777; #endif if (trans_mkdir(UNIX_DIR, mode) == -1) { prmsg (1, "SocketUNIXResetListener: mkdir(%s) failed, errno = %d\n", UNIX_DIR, errno); (void) umask (oldUmask); return TRANS_RESET_FAILURE; } #endif close (ciptr->fd); unlink (unsock->sun_path); if ((ciptr->fd = socket (AF_UNIX, SOCK_STREAM, 0)) < 0) { TRANS(FreeConnInfo) (ciptr); (void) umask (oldUmask); return TRANS_RESET_FAILURE; } if (bind (ciptr->fd, (struct sockaddr *) unsock, ciptr->addrlen) < 0) { close (ciptr->fd); TRANS(FreeConnInfo) (ciptr); return TRANS_RESET_FAILURE; } if (listen (ciptr->fd, BACKLOG) < 0) { close (ciptr->fd); TRANS(FreeConnInfo) (ciptr); (void) umask (oldUmask); return TRANS_RESET_FAILURE; } umask (oldUmask); status = TRANS_RESET_NEW_FD; } return status; } #endif /* UNIXCONN */ #ifdef TCPCONN static XtransConnInfo TRANS(SocketINETAccept) (XtransConnInfo ciptr, int *status) { XtransConnInfo newciptr; #if defined(IPv6) && defined(AF_INET6) struct sockaddr_storage sockname; #else struct sockaddr_in sockname; #endif SOCKLEN_T namelen = sizeof(sockname); prmsg (2, "SocketINETAccept(%p,%d)\n", ciptr, ciptr->fd); if ((newciptr = calloc (1, sizeof(struct _XtransConnInfo))) == NULL) { prmsg (1, "SocketINETAccept: malloc failed\n"); *status = TRANS_ACCEPT_BAD_MALLOC; return NULL; } if ((newciptr->fd = accept (ciptr->fd, (struct sockaddr *) &sockname, (void *)&namelen)) < 0) { #ifdef WIN32 errno = WSAGetLastError(); #endif prmsg (1, "SocketINETAccept: accept() failed\n"); free (newciptr); *status = TRANS_ACCEPT_FAILED; return NULL; } #ifdef TCP_NODELAY { /* * turn off TCP coalescence for INET sockets */ int tmp = 1; setsockopt (newciptr->fd, IPPROTO_TCP, TCP_NODELAY, (char *) &tmp, sizeof (int)); } #endif /* * Get this address again because the transport may give a more * specific address now that a connection is established. */ if (TRANS(SocketINETGetAddr) (newciptr) < 0) { prmsg (1, "SocketINETAccept: ...SocketINETGetAddr() failed:\n"); close (newciptr->fd); free (newciptr); *status = TRANS_ACCEPT_MISC_ERROR; return NULL; } if (TRANS(SocketINETGetPeerAddr) (newciptr) < 0) { prmsg (1, "SocketINETAccept: ...SocketINETGetPeerAddr() failed:\n"); close (newciptr->fd); if (newciptr->addr) free (newciptr->addr); free (newciptr); *status = TRANS_ACCEPT_MISC_ERROR; return NULL; } *status = 0; return newciptr; } #endif /* TCPCONN */ #ifdef UNIXCONN static XtransConnInfo TRANS(SocketUNIXAccept) (XtransConnInfo ciptr, int *status) { XtransConnInfo newciptr; struct sockaddr_un sockname; SOCKLEN_T namelen = sizeof sockname; prmsg (2, "SocketUNIXAccept(%p,%d)\n", ciptr, ciptr->fd); if ((newciptr = calloc (1, sizeof(struct _XtransConnInfo))) == NULL) { prmsg (1, "SocketUNIXAccept: malloc() failed\n"); *status = TRANS_ACCEPT_BAD_MALLOC; return NULL; } if ((newciptr->fd = accept (ciptr->fd, (struct sockaddr *) &sockname, (void *)&namelen)) < 0) { prmsg (1, "SocketUNIXAccept: accept() failed\n"); free (newciptr); *status = TRANS_ACCEPT_FAILED; return NULL; } ciptr->addrlen = namelen; /* * Get the socket name and the peer name from the listener socket, * since this is unix domain. */ if ((newciptr->addr = malloc (ciptr->addrlen)) == NULL) { prmsg (1, "SocketUNIXAccept: Can't allocate space for the addr\n"); close (newciptr->fd); free (newciptr); *status = TRANS_ACCEPT_BAD_MALLOC; return NULL; } /* * if the socket is abstract, we already modified the address to have a * @ instead of the initial NUL, so no need to do that again here. */ newciptr->addrlen = ciptr->addrlen; memcpy (newciptr->addr, ciptr->addr, newciptr->addrlen); if ((newciptr->peeraddr = malloc (ciptr->addrlen)) == NULL) { prmsg (1, "SocketUNIXAccept: Can't allocate space for the addr\n"); close (newciptr->fd); if (newciptr->addr) free (newciptr->addr); free (newciptr); *status = TRANS_ACCEPT_BAD_MALLOC; return NULL; } newciptr->peeraddrlen = ciptr->addrlen; memcpy (newciptr->peeraddr, ciptr->addr, newciptr->addrlen); newciptr->family = AF_UNIX; *status = 0; return newciptr; } #endif /* UNIXCONN */ #endif /* TRANS_SERVER */ #ifdef TRANS_CLIENT #ifdef TCPCONN #if defined(IPv6) && defined(AF_INET6) struct addrlist { struct addrinfo * addr; struct addrinfo * firstaddr; char port[PORTBUFSIZE]; char host[MAXHOSTNAMELEN]; }; static struct addrlist *addrlist = NULL; #endif static int TRANS(SocketINETConnect) (XtransConnInfo ciptr, char *host, char *port) { struct sockaddr * socketaddr = NULL; int socketaddrlen = 0; int res; #if defined(IPv6) && defined(AF_INET6) struct addrinfo hints; char ntopbuf[INET6_ADDRSTRLEN]; int resetonce = 0; #else struct sockaddr_in sockname; struct hostent *hostp; struct servent *servp; unsigned long tmpaddr; #endif #ifdef XTHREADS_NEEDS_BYNAMEPARAMS _Xgethostbynameparams hparams; _Xgetservbynameparams sparams; #endif #ifdef X11_t char portbuf[PORTBUFSIZE]; #endif char hostnamebuf[256]; /* tmp space */ prmsg (2,"SocketINETConnect(%d,%s,%s)\n", ciptr->fd, host, port); if (!host) { hostnamebuf[0] = '\0'; (void) TRANS(GetHostname) (hostnamebuf, sizeof hostnamebuf); host = hostnamebuf; } #ifdef X11_t /* * X has a well known port, that is transport dependent. It is easier * to handle it here, than try and come up with a transport independent * representation that can be passed in and resolved the usual way. * * The port that is passed here is really a string containing the idisplay * from ConnectDisplay(). */ if (is_numeric (port)) { long tmpport = X_TCP_PORT + strtol (port, (char**)NULL, 10); snprintf (portbuf, sizeof(portbuf), "%lu", tmpport); port = portbuf; } #endif #if defined(IPv6) && defined(AF_INET6) { if (addrlist != NULL) { if (strcmp(host,addrlist->host) || strcmp(port,addrlist->port)) { if (addrlist->firstaddr) freeaddrinfo(addrlist->firstaddr); addrlist->firstaddr = NULL; } } else { addrlist = malloc(sizeof(struct addrlist)); addrlist->firstaddr = NULL; } if (addrlist->firstaddr == NULL) { strncpy(addrlist->port, port, sizeof(addrlist->port)); addrlist->port[sizeof(addrlist->port) - 1] = '\0'; strncpy(addrlist->host, host, sizeof(addrlist->host)); addrlist->host[sizeof(addrlist->host) - 1] = '\0'; bzero(&hints,sizeof(hints)); hints.ai_socktype = Sockettrans2devtab[ciptr->index].devcotsname; res = getaddrinfo(host,port,&hints,&addrlist->firstaddr); if (res != 0) { prmsg (1, "SocketINETConnect() can't get address " "for %s:%s: %s\n", host, port, gai_strerror(res)); ESET(EINVAL); return TRANS_CONNECT_FAILED; } for (res = 0, addrlist->addr = addrlist->firstaddr; addrlist->addr ; res++) { addrlist->addr = addrlist->addr->ai_next; } prmsg(4,"Got New Address list with %d addresses\n", res); res = 0; addrlist->addr = NULL; } while (socketaddr == NULL) { if (addrlist->addr == NULL) { if (resetonce) { /* Already checked entire list - no usable addresses */ prmsg (1, "SocketINETConnect() no usable address " "for %s:%s\n", host, port); return TRANS_CONNECT_FAILED; } else { /* Go back to beginning of list */ resetonce = 1; addrlist->addr = addrlist->firstaddr; } } socketaddr = addrlist->addr->ai_addr; socketaddrlen = addrlist->addr->ai_addrlen; if (addrlist->addr->ai_family == AF_INET) { struct sockaddr_in *sin = (struct sockaddr_in *) socketaddr; prmsg (4,"SocketINETConnect() sockname.sin_addr = %s\n", inet_ntop(addrlist->addr->ai_family,&sin->sin_addr, ntopbuf,sizeof(ntopbuf))); prmsg (4,"SocketINETConnect() sockname.sin_port = %d\n", ntohs(sin->sin_port)); if (Sockettrans2devtab[ciptr->index].family == AF_INET6) { if (strcmp(Sockettrans2devtab[ciptr->index].transname, "tcp") == 0) { XtransConnInfo newciptr; /* * Our socket is an IPv6 socket, but the address is * IPv4. Close it and get an IPv4 socket. This is * needed for IPv4 connections to work on platforms * that don't allow IPv4 over IPv6 sockets. */ TRANS(SocketINETClose)(ciptr); newciptr = TRANS(SocketOpenCOTSClientBase)( "tcp", "tcp", host, port, ciptr->index); if (newciptr) ciptr->fd = newciptr->fd; if (!newciptr || Sockettrans2devtab[newciptr->index].family != AF_INET) { socketaddr = NULL; prmsg (4,"SocketINETConnect() Cannot get IPv4 " " socketfor IPv4 address\n"); } if (newciptr) free(newciptr); } else { socketaddr = NULL; prmsg (4,"SocketINETConnect Skipping IPv4 address\n"); } } } else if (addrlist->addr->ai_family == AF_INET6) { struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *) socketaddr; prmsg (4,"SocketINETConnect() sockname.sin6_addr = %s\n", inet_ntop(addrlist->addr->ai_family, &sin6->sin6_addr,ntopbuf,sizeof(ntopbuf))); prmsg (4,"SocketINETConnect() sockname.sin6_port = %d\n", ntohs(sin6->sin6_port)); if (Sockettrans2devtab[ciptr->index].family == AF_INET) { if (strcmp(Sockettrans2devtab[ciptr->index].transname, "tcp") == 0) { XtransConnInfo newciptr; /* * Close the IPv4 socket and try to open an IPv6 socket. */ TRANS(SocketINETClose)(ciptr); newciptr = TRANS(SocketOpenCOTSClientBase)( "tcp", "tcp", host, port, -1); if (newciptr) ciptr->fd = newciptr->fd; if (!newciptr || Sockettrans2devtab[newciptr->index].family != AF_INET6) { socketaddr = NULL; prmsg (4,"SocketINETConnect() Cannot get IPv6 " "socket for IPv6 address\n"); } if (newciptr) free(newciptr); } else { socketaddr = NULL; prmsg (4,"SocketINETConnect() Skipping IPv6 address\n"); } } } else { socketaddr = NULL; /* Unsupported address type */ } if (socketaddr == NULL) { addrlist->addr = addrlist->addr->ai_next; } } } #else { /* * Build the socket name. */ #ifdef BSD44SOCKETS sockname.sin_len = sizeof (struct sockaddr_in); #endif sockname.sin_family = AF_INET; /* * fill in sin_addr */ #ifndef INADDR_NONE #define INADDR_NONE ((in_addr_t) 0xffffffff) #endif /* check for ww.xx.yy.zz host string */ if (isascii (host[0]) && isdigit (host[0])) { tmpaddr = inet_addr (host); /* returns network byte order */ } else { tmpaddr = INADDR_NONE; } prmsg (4,"SocketINETConnect() inet_addr(%s) = %x\n", host, tmpaddr); if (tmpaddr == INADDR_NONE) { if ((hostp = _XGethostbyname(host,hparams)) == NULL) { prmsg (1,"SocketINETConnect: Can't get address for %s\n", host); ESET(EINVAL); return TRANS_CONNECT_FAILED; } if (hostp->h_addrtype != AF_INET) { /* is IP host? */ prmsg (1,"SocketINETConnect: not INET host%s\n", host); ESET(EPROTOTYPE); return TRANS_CONNECT_FAILED; } memcpy ((char *) &sockname.sin_addr, (char *) hostp->h_addr, sizeof (sockname.sin_addr)); } else { sockname.sin_addr.s_addr = tmpaddr; } /* * fill in sin_port */ /* Check for number in the port string */ if (!is_numeric (port)) { if ((servp = _XGetservbyname (port,"tcp",sparams)) == NULL) { prmsg (1,"SocketINETConnect: can't get service for %s\n", port); return TRANS_CONNECT_FAILED; } sockname.sin_port = htons (servp->s_port); } else { long tmpport = strtol (port, (char**)NULL, 10); if (tmpport < 1024 || tmpport > USHRT_MAX) return TRANS_CONNECT_FAILED; sockname.sin_port = htons (((unsigned short) tmpport)); } prmsg (4,"SocketINETConnect: sockname.sin_port = %d\n", ntohs(sockname.sin_port)); socketaddr = (struct sockaddr *) &sockname; socketaddrlen = sizeof(sockname); } #endif /* * Turn on socket keepalive so the client process will eventually * be notified with a SIGPIPE signal if the display server fails * to respond to a periodic transmission of messages * on the connected socket. * This is useful to avoid hung application processes when the * processes are not spawned from the xdm session and * the display server terminates abnormally. * (Someone turned off the power switch.) */ { int tmp = 1; setsockopt (ciptr->fd, SOL_SOCKET, SO_KEEPALIVE, (char *) &tmp, sizeof (int)); } /* * Do the connect() */ if (connect (ciptr->fd, socketaddr, socketaddrlen ) < 0) { #ifdef WIN32 int olderrno = WSAGetLastError(); #else int olderrno = errno; #endif /* * If the error was ECONNREFUSED, the server may be overloaded * and we should try again. * * If the error was EWOULDBLOCK or EINPROGRESS then the socket * was non-blocking and we should poll using select * * If the error was EINTR, the connect was interrupted and we * should try again. * * If multiple addresses are found for a host then we should * try to connect again with a different address for a larger * number of errors that made us quit before, since those * could be caused by trying to use an IPv6 address to contact * a machine with an IPv4-only server or other reasons that * only affect one of a set of addresses. */ if (olderrno == ECONNREFUSED || olderrno == EINTR #if defined(IPv6) && defined(AF_INET6) || (((addrlist->addr->ai_next != NULL) || (addrlist->addr != addrlist->firstaddr)) && (olderrno == ENETUNREACH || olderrno == EAFNOSUPPORT || olderrno == EADDRNOTAVAIL || olderrno == ETIMEDOUT #if defined(EHOSTDOWN) || olderrno == EHOSTDOWN #endif )) #endif ) res = TRANS_TRY_CONNECT_AGAIN; else if (olderrno == EWOULDBLOCK || olderrno == EINPROGRESS) res = TRANS_IN_PROGRESS; else { prmsg (2,"SocketINETConnect: Can't connect: errno = %d\n", olderrno); res = TRANS_CONNECT_FAILED; } } else { res = 0; /* * Sync up the address fields of ciptr. */ if (TRANS(SocketINETGetAddr) (ciptr) < 0) { prmsg (1, "SocketINETConnect: ...SocketINETGetAddr() failed:\n"); res = TRANS_CONNECT_FAILED; } else if (TRANS(SocketINETGetPeerAddr) (ciptr) < 0) { prmsg (1, "SocketINETConnect: ...SocketINETGetPeerAddr() failed:\n"); res = TRANS_CONNECT_FAILED; } } #if defined(IPv6) && defined(AF_INET6) if (res != 0) { addrlist->addr = addrlist->addr->ai_next; } #endif return res; } #endif /* TCPCONN */ #ifdef UNIXCONN /* * Make sure 'host' is really local. */ static int UnixHostReallyLocal (char *host) { char hostnamebuf[256]; TRANS(GetHostname) (hostnamebuf, sizeof (hostnamebuf)); if (strcmp (hostnamebuf, host) == 0) { return (1); } else { #if defined(IPv6) && defined(AF_INET6) struct addrinfo *localhostaddr; struct addrinfo *otherhostaddr; struct addrinfo *i, *j; int equiv = 0; if (getaddrinfo(hostnamebuf, NULL, NULL, &localhostaddr) != 0) return 0; if (getaddrinfo(host, NULL, NULL, &otherhostaddr) != 0) { freeaddrinfo(localhostaddr); return 0; } for (i = localhostaddr; i != NULL && equiv == 0; i = i->ai_next) { for (j = otherhostaddr; j != NULL && equiv == 0; j = j->ai_next) { if (i->ai_family == j->ai_family) { if (i->ai_family == AF_INET) { struct sockaddr_in *sinA = (struct sockaddr_in *) i->ai_addr; struct sockaddr_in *sinB = (struct sockaddr_in *) j->ai_addr; struct in_addr *A = &sinA->sin_addr; struct in_addr *B = &sinB->sin_addr; if (memcmp(A,B,sizeof(struct in_addr)) == 0) { equiv = 1; } } else if (i->ai_family == AF_INET6) { struct sockaddr_in6 *sinA = (struct sockaddr_in6 *) i->ai_addr; struct sockaddr_in6 *sinB = (struct sockaddr_in6 *) j->ai_addr; struct in6_addr *A = &sinA->sin6_addr; struct in6_addr *B = &sinB->sin6_addr; if (memcmp(A,B,sizeof(struct in6_addr)) == 0) { equiv = 1; } } } } } freeaddrinfo(localhostaddr); freeaddrinfo(otherhostaddr); return equiv; #else /* * A host may have more than one network address. If any of the * network addresses of 'host' (specified to the connect call) * match any of the network addresses of 'hostname' (determined * by TRANS(GetHostname)), then the two hostnames are equivalent, * and we know that 'host' is really a local host. */ char specified_local_addr_list[10][4]; int scount, equiv, i, j; #ifdef XTHREADS_NEEDS_BYNAMEPARAMS _Xgethostbynameparams hparams; #endif struct hostent *hostp; if ((hostp = _XGethostbyname (host,hparams)) == NULL) return (0); scount = 0; while (hostp->h_addr_list[scount] && scount <= 8) { /* * The 2nd call to gethostname() overrides the data * from the 1st call, so we must save the address list. */ specified_local_addr_list[scount][0] = hostp->h_addr_list[scount][0]; specified_local_addr_list[scount][1] = hostp->h_addr_list[scount][1]; specified_local_addr_list[scount][2] = hostp->h_addr_list[scount][2]; specified_local_addr_list[scount][3] = hostp->h_addr_list[scount][3]; scount++; } if ((hostp = _XGethostbyname (hostnamebuf,hparams)) == NULL) return (0); equiv = 0; i = 0; while (i < scount && !equiv) { j = 0; while (hostp->h_addr_list[j]) { if ((specified_local_addr_list[i][0] == hostp->h_addr_list[j][0]) && (specified_local_addr_list[i][1] == hostp->h_addr_list[j][1]) && (specified_local_addr_list[i][2] == hostp->h_addr_list[j][2]) && (specified_local_addr_list[i][3] == hostp->h_addr_list[j][3])) { /* They're equal, so we're done */ equiv = 1; break; } j++; } i++; } return (equiv); #endif } } static int TRANS(SocketUNIXConnect) (XtransConnInfo ciptr, char *host, char *port) { struct sockaddr_un sockname; SOCKLEN_T namelen; int abstract = 0; #ifdef HAVE_ABSTRACT_SOCKETS abstract = ciptr->transptr->flags & TRANS_ABSTRACT; #endif prmsg (2,"SocketUNIXConnect(%d,%s,%s)\n", ciptr->fd, host, port); /* * Make sure 'host' is really local. If not, we return failure. * The reason we make this check is because a process may advertise * a "local" network ID for which it can accept connections, but if * a process on a remote machine tries to connect to this network ID, * we know for sure it will fail. */ if (host && *host && host[0]!='/' && strcmp (host, "unix") != 0 && !UnixHostReallyLocal (host)) { prmsg (1, "SocketUNIXConnect: Cannot connect to non-local host %s\n", host); return TRANS_CONNECT_FAILED; } /* * Check the port. */ if (!port || !*port) { prmsg (1,"SocketUNIXConnect: Missing port specification\n"); return TRANS_CONNECT_FAILED; } /* * Build the socket name. */ sockname.sun_family = AF_UNIX; if (set_sun_path(port, UNIX_PATH, sockname.sun_path, abstract) != 0) { prmsg (1, "SocketUNIXConnect: path too long\n"); return TRANS_CONNECT_FAILED; } #if (defined(BSD44SOCKETS) || defined(__UNIXWARE__)) sockname.sun_len = strlen (sockname.sun_path); #endif #if defined(BSD44SOCKETS) || defined(SUN_LEN) namelen = SUN_LEN (&sockname); #else namelen = strlen (sockname.sun_path) + offsetof(struct sockaddr_un, sun_path); #endif /* * Adjust the socket path if using abstract sockets. * Done here because otherwise all the strlen() calls above would fail. */ if (abstract) { sockname.sun_path[0] = '\0'; } /* * Do the connect() */ if (connect (ciptr->fd, (struct sockaddr *) &sockname, namelen) < 0) { int olderrno = errno; int connected = 0; if (!connected) { errno = olderrno; /* * If the error was ENOENT, the server may be starting up; we used * to suggest to try again in this case with * TRANS_TRY_CONNECT_AGAIN, but this introduced problems for * processes still referencing stale sockets in their environment. * Hence, we now return a hard error, TRANS_CONNECT_FAILED, and it * is suggested that higher level stacks handle retries on their * level when they face a slow starting server. * * If the error was EWOULDBLOCK or EINPROGRESS then the socket * was non-blocking and we should poll using select * * If the error was EINTR, the connect was interrupted and we * should try again. */ if (olderrno == EWOULDBLOCK || olderrno == EINPROGRESS) return TRANS_IN_PROGRESS; else if (olderrno == EINTR) return TRANS_TRY_CONNECT_AGAIN; else if (olderrno == ENOENT || olderrno == ECONNREFUSED) { /* If opening as abstract socket failed, try again normally */ if (abstract) { ciptr->transptr->flags &= ~(TRANS_ABSTRACT); return TRANS_TRY_CONNECT_AGAIN; } else { return TRANS_CONNECT_FAILED; } } else { prmsg (2,"SocketUNIXConnect: Can't connect: errno = %d\n", EGET()); return TRANS_CONNECT_FAILED; } } } /* * Get the socket name and the peer name from the connect socket, * since this is unix domain. */ if ((ciptr->addr = malloc(namelen)) == NULL || (ciptr->peeraddr = malloc(namelen)) == NULL) { prmsg (1, "SocketUNIXCreateListener: Can't allocate space for the addr\n"); return TRANS_CONNECT_FAILED; } if (abstract) sockname.sun_path[0] = '@'; ciptr->family = AF_UNIX; ciptr->addrlen = namelen; ciptr->peeraddrlen = namelen; memcpy (ciptr->addr, &sockname, ciptr->addrlen); memcpy (ciptr->peeraddr, &sockname, ciptr->peeraddrlen); return 0; } #endif /* UNIXCONN */ #endif /* TRANS_CLIENT */ static int TRANS(SocketBytesReadable) (XtransConnInfo ciptr, BytesReadable_t *pend) { prmsg (2,"SocketBytesReadable(%p,%d,%p)\n", ciptr, ciptr->fd, pend); #ifdef WIN32 { int ret = ioctlsocket ((SOCKET) ciptr->fd, FIONREAD, (u_long *) pend); if (ret == SOCKET_ERROR) errno = WSAGetLastError(); return ret; } #else #if defined(__i386__) && defined(SYSV) && !defined(SCO325) return ioctl (ciptr->fd, I_NREAD, (char *) pend); #else return ioctl (ciptr->fd, FIONREAD, (char *) pend); #endif /* __i386__ && SYSV || _SEQUENT_ && _SOCKET_VERSION == 1 */ #endif /* WIN32 */ } #if XTRANS_SEND_FDS static void appendFd(struct _XtransConnFd **prev, int fd, int do_close) { struct _XtransConnFd *cf, *new; new = malloc (sizeof (struct _XtransConnFd)); if (!new) { /* XXX mark connection as broken */ close(fd); return; } new->next = 0; new->fd = fd; new->do_close = do_close; /* search to end of list */ for (; (cf = *prev); prev = &(cf->next)); *prev = new; } static int removeFd(struct _XtransConnFd **prev) { struct _XtransConnFd *cf; int fd; if ((cf = *prev)) { *prev = cf->next; fd = cf->fd; free(cf); } else fd = -1; return fd; } static void discardFd(struct _XtransConnFd **prev, struct _XtransConnFd *upto, int do_close) { struct _XtransConnFd *cf, *next; for (cf = *prev; cf != upto; cf = next) { next = cf->next; if (do_close || cf->do_close) close(cf->fd); free(cf); } *prev = upto; } static void cleanupFds(XtransConnInfo ciptr) { /* Clean up the send list but don't close the fds */ discardFd(&ciptr->send_fds, NULL, 0); /* Clean up the recv list and *do* close the fds */ discardFd(&ciptr->recv_fds, NULL, 1); } static int nFd(struct _XtransConnFd **prev) { struct _XtransConnFd *cf; int n = 0; for (cf = *prev; cf; cf = cf->next) n++; return n; } static int TRANS(SocketRecvFd) (XtransConnInfo ciptr) { prmsg (2, "SocketRecvFd(%d)\n", ciptr->fd); return removeFd(&ciptr->recv_fds); } static int TRANS(SocketSendFd) (XtransConnInfo ciptr, int fd, int do_close) { appendFd(&ciptr->send_fds, fd, do_close); return 0; } static int TRANS(SocketRecvFdInvalid)(XtransConnInfo ciptr) { errno = EINVAL; return -1; } static int TRANS(SocketSendFdInvalid)(XtransConnInfo ciptr, int fd, int do_close) { errno = EINVAL; return -1; } #define MAX_FDS 128 struct fd_pass { struct cmsghdr cmsghdr; int fd[MAX_FDS]; }; static inline void init_msg_recv(struct msghdr *msg, struct iovec *iov, int niov, struct fd_pass *pass, int nfd) { msg->msg_name = NULL; msg->msg_namelen = 0; msg->msg_iov = iov; msg->msg_iovlen = niov; msg->msg_control = pass; msg->msg_controllen = sizeof (struct cmsghdr) + nfd * sizeof (int); } static inline void init_msg_send(struct msghdr *msg, struct iovec *iov, int niov, struct fd_pass *pass, int nfd) { init_msg_recv(msg, iov, niov, pass, nfd); pass->cmsghdr.cmsg_len = msg->msg_controllen; pass->cmsghdr.cmsg_level = SOL_SOCKET; pass->cmsghdr.cmsg_type = SCM_RIGHTS; } #endif /* XTRANS_SEND_FDS */ static int TRANS(SocketRead) (XtransConnInfo ciptr, char *buf, int size) { prmsg (2,"SocketRead(%d,%p,%d)\n", ciptr->fd, buf, size); #if defined(WIN32) { int ret = recv ((SOCKET)ciptr->fd, buf, size, 0); #ifdef WIN32 if (ret == SOCKET_ERROR) errno = WSAGetLastError(); #endif return ret; } #else #if XTRANS_SEND_FDS { struct iovec iov = { .iov_base = buf, .iov_len = size }; char cmsgbuf[CMSG_SPACE(sizeof(int) * MAX_FDS)]; struct msghdr msg = { .msg_name = NULL, .msg_namelen = 0, .msg_iov = &iov, .msg_iovlen = 1, .msg_control = cmsgbuf, .msg_controllen = CMSG_LEN(MAX_FDS * sizeof(int)) }; size = recvmsg(ciptr->fd, &msg, 0); if (size >= 0) { struct cmsghdr *hdr; for (hdr = CMSG_FIRSTHDR(&msg); hdr; hdr = CMSG_NXTHDR(&msg, hdr)) { if (hdr->cmsg_level == SOL_SOCKET && hdr->cmsg_type == SCM_RIGHTS) { int nfd = (hdr->cmsg_len - CMSG_LEN(0)) / sizeof (int); int i; int *fd = (int *) CMSG_DATA(hdr); for (i = 0; i < nfd; i++) appendFd(&ciptr->recv_fds, fd[i], 0); } } } return size; } #else return read(ciptr->fd, buf, size); #endif /* XTRANS_SEND_FDS */ #endif /* WIN32 */ } static int TRANS(SocketReadv) (XtransConnInfo ciptr, struct iovec *buf, int size) { prmsg (2,"SocketReadv(%d,%p,%d)\n", ciptr->fd, buf, size); #if XTRANS_SEND_FDS { char cmsgbuf[CMSG_SPACE(sizeof(int) * MAX_FDS)]; struct msghdr msg = { .msg_name = NULL, .msg_namelen = 0, .msg_iov = buf, .msg_iovlen = size, .msg_control = cmsgbuf, .msg_controllen = CMSG_LEN(MAX_FDS * sizeof(int)) }; size = recvmsg(ciptr->fd, &msg, 0); if (size >= 0) { struct cmsghdr *hdr; for (hdr = CMSG_FIRSTHDR(&msg); hdr; hdr = CMSG_NXTHDR(&msg, hdr)) { if (hdr->cmsg_level == SOL_SOCKET && hdr->cmsg_type == SCM_RIGHTS) { int nfd = (hdr->cmsg_len - CMSG_LEN(0)) / sizeof (int); int i; int *fd = (int *) CMSG_DATA(hdr); for (i = 0; i < nfd; i++) appendFd(&ciptr->recv_fds, fd[i], 0); } } } return size; } #else return READV (ciptr, buf, size); #endif } static int TRANS(SocketWritev) (XtransConnInfo ciptr, struct iovec *buf, int size) { prmsg (2,"SocketWritev(%d,%p,%d)\n", ciptr->fd, buf, size); #if XTRANS_SEND_FDS if (ciptr->send_fds) { char cmsgbuf[CMSG_SPACE(sizeof(int) * MAX_FDS)]; int nfd = nFd(&ciptr->send_fds); struct _XtransConnFd *cf = ciptr->send_fds; struct msghdr msg = { .msg_name = NULL, .msg_namelen = 0, .msg_iov = buf, .msg_iovlen = size, .msg_control = cmsgbuf, .msg_controllen = CMSG_LEN(nfd * sizeof(int)) }; struct cmsghdr *hdr = CMSG_FIRSTHDR(&msg); int i; int *fds; hdr->cmsg_len = msg.msg_controllen; hdr->cmsg_level = SOL_SOCKET; hdr->cmsg_type = SCM_RIGHTS; fds = (int *) CMSG_DATA(hdr); /* Set up fds */ for (i = 0; i < nfd; i++) { fds[i] = cf->fd; cf = cf->next; } i = sendmsg(ciptr->fd, &msg, 0); if (i > 0) discardFd(&ciptr->send_fds, cf, 0); return i; } #endif return WRITEV (ciptr, buf, size); } static int TRANS(SocketWrite) (XtransConnInfo ciptr, char *buf, int size) { prmsg (2,"SocketWrite(%d,%p,%d)\n", ciptr->fd, buf, size); #if defined(WIN32) { int ret = send ((SOCKET)ciptr->fd, buf, size, 0); #ifdef WIN32 if (ret == SOCKET_ERROR) errno = WSAGetLastError(); #endif return ret; } #else #if XTRANS_SEND_FDS if (ciptr->send_fds) { struct iovec iov; iov.iov_base = buf; iov.iov_len = size; return TRANS(SocketWritev)(ciptr, &iov, 1); } #endif /* XTRANS_SEND_FDS */ return write (ciptr->fd, buf, size); #endif /* WIN32 */ } static int TRANS(SocketDisconnect) (XtransConnInfo ciptr) { prmsg (2,"SocketDisconnect(%p,%d)\n", ciptr, ciptr->fd); #ifdef WIN32 { int ret = shutdown (ciptr->fd, 2); if (ret == SOCKET_ERROR) errno = WSAGetLastError(); return ret; } #else return shutdown (ciptr->fd, 2); /* disallow further sends and receives */ #endif } #ifdef TCPCONN static int TRANS(SocketINETClose) (XtransConnInfo ciptr) { prmsg (2,"SocketINETClose(%p,%d)\n", ciptr, ciptr->fd); #ifdef WIN32 { int ret = close (ciptr->fd); if (ret == SOCKET_ERROR) errno = WSAGetLastError(); return ret; } #else return close (ciptr->fd); #endif } #endif /* TCPCONN */ #ifdef UNIXCONN static int TRANS(SocketUNIXClose) (XtransConnInfo ciptr) { /* * If this is the server side, then once the socket is closed, * it must be unlinked to completely close it */ struct sockaddr_un *sockname = (struct sockaddr_un *) ciptr->addr; int ret; prmsg (2,"SocketUNIXClose(%p,%d)\n", ciptr, ciptr->fd); #if XTRANS_SEND_FDS cleanupFds(ciptr); #endif ret = close(ciptr->fd); if (ciptr->flags && sockname && sockname->sun_family == AF_UNIX && sockname->sun_path[0]) { if (!(ciptr->flags & TRANS_NOUNLINK || ciptr->transptr->flags & TRANS_ABSTRACT)) unlink (sockname->sun_path); } return ret; } static int TRANS(SocketUNIXCloseForCloning) (XtransConnInfo ciptr) { /* * Don't unlink path. */ int ret; prmsg (2,"SocketUNIXCloseForCloning(%p,%d)\n", ciptr, ciptr->fd); #if XTRANS_SEND_FDS cleanupFds(ciptr); #endif ret = close(ciptr->fd); return ret; } #endif /* UNIXCONN */ #ifdef TCPCONN # ifdef TRANS_SERVER static const char* tcp_nolisten[] = { "inet", #if defined(IPv6) && defined(AF_INET6) "inet6", #endif NULL }; # endif Xtransport TRANS(SocketTCPFuncs) = { /* Socket Interface */ "tcp", TRANS_ALIAS, #ifdef TRANS_CLIENT TRANS(SocketOpenCOTSClient), #endif /* TRANS_CLIENT */ #ifdef TRANS_SERVER tcp_nolisten, TRANS(SocketOpenCOTSServer), #endif /* TRANS_SERVER */ #ifdef TRANS_CLIENT TRANS(SocketOpenCLTSClient), #endif /* TRANS_CLIENT */ #ifdef TRANS_SERVER TRANS(SocketOpenCLTSServer), #endif /* TRANS_SERVER */ #ifdef TRANS_REOPEN TRANS(SocketReopenCOTSServer), TRANS(SocketReopenCLTSServer), #endif TRANS(SocketSetOption), #ifdef TRANS_SERVER TRANS(SocketINETCreateListener), NULL, /* ResetListener */ TRANS(SocketINETAccept), #endif /* TRANS_SERVER */ #ifdef TRANS_CLIENT TRANS(SocketINETConnect), #endif /* TRANS_CLIENT */ TRANS(SocketBytesReadable), TRANS(SocketRead), TRANS(SocketWrite), TRANS(SocketReadv), TRANS(SocketWritev), #if XTRANS_SEND_FDS TRANS(SocketSendFdInvalid), TRANS(SocketRecvFdInvalid), #endif TRANS(SocketDisconnect), TRANS(SocketINETClose), TRANS(SocketINETClose), }; Xtransport TRANS(SocketINETFuncs) = { /* Socket Interface */ "inet", 0, #ifdef TRANS_CLIENT TRANS(SocketOpenCOTSClient), #endif /* TRANS_CLIENT */ #ifdef TRANS_SERVER NULL, TRANS(SocketOpenCOTSServer), #endif /* TRANS_SERVER */ #ifdef TRANS_CLIENT TRANS(SocketOpenCLTSClient), #endif /* TRANS_CLIENT */ #ifdef TRANS_SERVER TRANS(SocketOpenCLTSServer), #endif /* TRANS_SERVER */ #ifdef TRANS_REOPEN TRANS(SocketReopenCOTSServer), TRANS(SocketReopenCLTSServer), #endif TRANS(SocketSetOption), #ifdef TRANS_SERVER TRANS(SocketINETCreateListener), NULL, /* ResetListener */ TRANS(SocketINETAccept), #endif /* TRANS_SERVER */ #ifdef TRANS_CLIENT TRANS(SocketINETConnect), #endif /* TRANS_CLIENT */ TRANS(SocketBytesReadable), TRANS(SocketRead), TRANS(SocketWrite), TRANS(SocketReadv), TRANS(SocketWritev), #if XTRANS_SEND_FDS TRANS(SocketSendFdInvalid), TRANS(SocketRecvFdInvalid), #endif TRANS(SocketDisconnect), TRANS(SocketINETClose), TRANS(SocketINETClose), }; #if defined(IPv6) && defined(AF_INET6) Xtransport TRANS(SocketINET6Funcs) = { /* Socket Interface */ "inet6", 0, #ifdef TRANS_CLIENT TRANS(SocketOpenCOTSClient), #endif /* TRANS_CLIENT */ #ifdef TRANS_SERVER NULL, TRANS(SocketOpenCOTSServer), #endif /* TRANS_SERVER */ #ifdef TRANS_CLIENT TRANS(SocketOpenCLTSClient), #endif /* TRANS_CLIENT */ #ifdef TRANS_SERVER TRANS(SocketOpenCLTSServer), #endif /* TRANS_SERVER */ #ifdef TRANS_REOPEN TRANS(SocketReopenCOTSServer), TRANS(SocketReopenCLTSServer), #endif TRANS(SocketSetOption), #ifdef TRANS_SERVER TRANS(SocketINETCreateListener), NULL, /* ResetListener */ TRANS(SocketINETAccept), #endif /* TRANS_SERVER */ #ifdef TRANS_CLIENT TRANS(SocketINETConnect), #endif /* TRANS_CLIENT */ TRANS(SocketBytesReadable), TRANS(SocketRead), TRANS(SocketWrite), TRANS(SocketReadv), TRANS(SocketWritev), #if XTRANS_SEND_FDS TRANS(SocketSendFdInvalid), TRANS(SocketRecvFdInvalid), #endif TRANS(SocketDisconnect), TRANS(SocketINETClose), TRANS(SocketINETClose), }; #endif /* IPv6 */ #endif /* TCPCONN */ #ifdef UNIXCONN #if !defined(LOCALCONN) Xtransport TRANS(SocketLocalFuncs) = { /* Socket Interface */ "local", #ifdef HAVE_ABSTRACT_SOCKETS TRANS_ABSTRACT, #else 0, #endif #ifdef TRANS_CLIENT TRANS(SocketOpenCOTSClient), #endif /* TRANS_CLIENT */ #ifdef TRANS_SERVER NULL, TRANS(SocketOpenCOTSServer), #endif /* TRANS_SERVER */ #ifdef TRANS_CLIENT TRANS(SocketOpenCLTSClient), #endif /* TRANS_CLIENT */ #ifdef TRANS_SERVER TRANS(SocketOpenCLTSServer), #endif /* TRANS_SERVER */ #ifdef TRANS_REOPEN TRANS(SocketReopenCOTSServer), TRANS(SocketReopenCLTSServer), #endif TRANS(SocketSetOption), #ifdef TRANS_SERVER TRANS(SocketUNIXCreateListener), TRANS(SocketUNIXResetListener), TRANS(SocketUNIXAccept), #endif /* TRANS_SERVER */ #ifdef TRANS_CLIENT TRANS(SocketUNIXConnect), #endif /* TRANS_CLIENT */ TRANS(SocketBytesReadable), TRANS(SocketRead), TRANS(SocketWrite), TRANS(SocketReadv), TRANS(SocketWritev), #if XTRANS_SEND_FDS TRANS(SocketSendFd), TRANS(SocketRecvFd), #endif TRANS(SocketDisconnect), TRANS(SocketUNIXClose), TRANS(SocketUNIXCloseForCloning), }; #endif /* !LOCALCONN */ # ifdef TRANS_SERVER # if !defined(LOCALCONN) static const char* unix_nolisten[] = { "local" , NULL }; # endif # endif Xtransport TRANS(SocketUNIXFuncs) = { /* Socket Interface */ "unix", #if !defined(LOCALCONN) && !defined(HAVE_ABSTRACT_SOCKETS) TRANS_ALIAS, #else 0, #endif #ifdef TRANS_CLIENT TRANS(SocketOpenCOTSClient), #endif /* TRANS_CLIENT */ #ifdef TRANS_SERVER #if !defined(LOCALCONN) unix_nolisten, #else NULL, #endif TRANS(SocketOpenCOTSServer), #endif /* TRANS_SERVER */ #ifdef TRANS_CLIENT TRANS(SocketOpenCLTSClient), #endif /* TRANS_CLIENT */ #ifdef TRANS_SERVER TRANS(SocketOpenCLTSServer), #endif /* TRANS_SERVER */ #ifdef TRANS_REOPEN TRANS(SocketReopenCOTSServer), TRANS(SocketReopenCLTSServer), #endif TRANS(SocketSetOption), #ifdef TRANS_SERVER TRANS(SocketUNIXCreateListener), TRANS(SocketUNIXResetListener), TRANS(SocketUNIXAccept), #endif /* TRANS_SERVER */ #ifdef TRANS_CLIENT TRANS(SocketUNIXConnect), #endif /* TRANS_CLIENT */ TRANS(SocketBytesReadable), TRANS(SocketRead), TRANS(SocketWrite), TRANS(SocketReadv), TRANS(SocketWritev), #if XTRANS_SEND_FDS TRANS(SocketSendFd), TRANS(SocketRecvFd), #endif TRANS(SocketDisconnect), TRANS(SocketUNIXClose), TRANS(SocketUNIXCloseForCloning), }; #endif /* UNIXCONN */