/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "primpl.h" #include #if defined(LINUX) #include #endif /* * On Unix, the error code for gethostbyname() and gethostbyaddr() * is returned in the global variable h_errno, instead of the usual * errno. */ #if defined(XP_UNIX) #if defined(_PR_NEED_H_ERRNO) extern int h_errno; #endif #define _MD_GETHOST_ERRNO() h_errno #else #define _MD_GETHOST_ERRNO() _MD_ERRNO() #endif /* * The meaning of the macros related to gethostbyname, gethostbyaddr, * and gethostbyname2 is defined below. * - _PR_HAVE_THREADSAFE_GETHOST: the gethostbyXXX functions return * the result in thread specific storage. For example, AIX, HP-UX. * - _PR_HAVE_GETHOST_R: have the gethostbyXXX_r functions. See next * two macros. * - _PR_HAVE_GETHOST_R_INT: the gethostbyXXX_r functions return an * int. For example, Linux glibc. * - _PR_HAVE_GETHOST_R_POINTER: the gethostbyXXX_r functions return * a struct hostent* pointer. For example, Solaris. */ #if defined(_PR_NO_PREEMPT) || defined(_PR_HAVE_GETHOST_R) \ || defined(_PR_HAVE_THREADSAFE_GETHOST) #define _PR_NO_DNS_LOCK #endif #if defined(_PR_NO_DNS_LOCK) #define LOCK_DNS() #define UNLOCK_DNS() #else PRLock *_pr_dnsLock = NULL; #define LOCK_DNS() PR_Lock(_pr_dnsLock) #define UNLOCK_DNS() PR_Unlock(_pr_dnsLock) #endif /* defined(_PR_NO_DNS_LOCK) */ /* * Some platforms have the reentrant getprotobyname_r() and * getprotobynumber_r(). However, they come in three flavors. * Some return a pointer to struct protoent, others return * an int, and glibc's flavor takes five arguments. */ #if defined(SOLARIS) || (defined(BSDI) && defined(_REENTRANT)) \ || (defined(LINUX) && defined(_REENTRANT) \ && defined(__GLIBC__) && __GLIBC__ < 2) #define _PR_HAVE_GETPROTO_R #define _PR_HAVE_GETPROTO_R_POINTER #endif #if defined(AIX4_3_PLUS) || (defined(AIX) && defined(_THREAD_SAFE)) \ || (defined(HPUX10_10) && defined(_REENTRANT)) \ || (defined(HPUX10_20) && defined(_REENTRANT)) \ || defined(OPENBSD) #define _PR_HAVE_GETPROTO_R #define _PR_HAVE_GETPROTO_R_INT #endif #if __FreeBSD_version >= 602000 #define _PR_HAVE_GETPROTO_R #define _PR_HAVE_5_ARG_GETPROTO_R #endif /* BeOS has glibc but not the glibc-style getprotobyxxx_r functions. */ #if (defined(__GLIBC__) && __GLIBC__ >= 2) #define _PR_HAVE_GETPROTO_R #define _PR_HAVE_5_ARG_GETPROTO_R #endif #if !defined(_PR_HAVE_GETPROTO_R) PRLock* _getproto_lock = NULL; #endif #if defined(_PR_INET6_PROBE) extern PRBool _pr_ipv6_is_present(void); #endif #define _PR_IN6_IS_ADDR_UNSPECIFIED(a) \ (((a)->pr_s6_addr32[0] == 0) && \ ((a)->pr_s6_addr32[1] == 0) && \ ((a)->pr_s6_addr32[2] == 0) && \ ((a)->pr_s6_addr32[3] == 0)) #define _PR_IN6_IS_ADDR_LOOPBACK(a) \ (((a)->pr_s6_addr32[0] == 0) && \ ((a)->pr_s6_addr32[1] == 0) && \ ((a)->pr_s6_addr32[2] == 0) && \ ((a)->pr_s6_addr[12] == 0) && \ ((a)->pr_s6_addr[13] == 0) && \ ((a)->pr_s6_addr[14] == 0) && \ ((a)->pr_s6_addr[15] == 0x1U)) const PRIPv6Addr _pr_in6addr_any = {{{ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 } } }; const PRIPv6Addr _pr_in6addr_loopback = {{{ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0x1U } } }; /* * The values at bytes 10 and 11 are compared using pointers to * 8-bit fields, and not 32-bit fields, to make the comparison work on * both big-endian and little-endian systems */ #define _PR_IN6_IS_ADDR_V4MAPPED(a) \ (((a)->pr_s6_addr32[0] == 0) && \ ((a)->pr_s6_addr32[1] == 0) && \ ((a)->pr_s6_addr[8] == 0) && \ ((a)->pr_s6_addr[9] == 0) && \ ((a)->pr_s6_addr[10] == 0xff) && \ ((a)->pr_s6_addr[11] == 0xff)) #define _PR_IN6_IS_ADDR_V4COMPAT(a) \ (((a)->pr_s6_addr32[0] == 0) && \ ((a)->pr_s6_addr32[1] == 0) && \ ((a)->pr_s6_addr32[2] == 0)) #define _PR_IN6_V4MAPPED_TO_IPADDR(a) ((a)->pr_s6_addr32[3]) #if defined(_PR_INET6) && defined(_PR_HAVE_GETHOSTBYNAME2) /* * The _pr_QueryNetIfs() function finds out if the system has * IPv4 or IPv6 source addresses configured and sets _pr_have_inet_if * and _pr_have_inet6_if accordingly. * * We have an implementation using SIOCGIFCONF ioctl and a * default implementation that simply sets _pr_have_inet_if * and _pr_have_inet6_if to true. A better implementation * would be to use the routing sockets (see Chapter 17 of * W. Richard Stevens' Unix Network Programming, Vol. 1, 2nd. Ed.) */ static PRLock *_pr_query_ifs_lock = NULL; static PRBool _pr_have_inet_if = PR_FALSE; static PRBool _pr_have_inet6_if = PR_FALSE; #undef DEBUG_QUERY_IFS #if defined(AIX) \ || (defined(DARWIN) && !defined(HAVE_GETIFADDRS)) /* * Use SIOCGIFCONF ioctl on platforms that don't have routing * sockets. Warning: whether SIOCGIFCONF ioctl returns AF_INET6 * network interfaces is not portable. * * The _pr_QueryNetIfs() function is derived from the code in * src/lib/libc/net/getifaddrs.c in BSD Unix and the code in * Section 16.6 of W. Richard Stevens' Unix Network Programming, * Vol. 1, 2nd. Ed. */ #include #include #include #include #ifdef DEBUG_QUERY_IFS static void _pr_PrintIfreq(struct ifreq *ifr) { PRNetAddr addr; struct sockaddr *sa; const char* family; char addrstr[64]; sa = &ifr->ifr_addr; if (sa->sa_family == AF_INET) { struct sockaddr_in *sin = (struct sockaddr_in *)sa; family = "inet"; memcpy(&addr.inet.ip, &sin->sin_addr, sizeof(sin->sin_addr)); } else if (sa->sa_family == AF_INET6) { struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *)sa; family = "inet6"; memcpy(&addr.ipv6.ip, &sin6->sin6_addr, sizeof(sin6->sin6_addr)); } else { return; /* skip if not AF_INET or AF_INET6 */ } addr.raw.family = sa->sa_family; PR_NetAddrToString(&addr, addrstr, sizeof(addrstr)); printf("%s: %s %s\n", ifr->ifr_name, family, addrstr); } #endif static void _pr_QueryNetIfs(void) { int sock; int rv; struct ifconf ifc; struct ifreq *ifr; struct ifreq *lifr; PRUint32 len, lastlen; char *buf; if ((sock = socket(AF_INET, SOCK_STREAM, 0)) == -1) { return; } /* Issue SIOCGIFCONF request in a loop. */ lastlen = 0; len = 100 * sizeof(struct ifreq); /* initial buffer size guess */ for (;;) { buf = (char *)PR_Malloc(len); if (NULL == buf) { close(sock); return; } ifc.ifc_buf = buf; ifc.ifc_len = len; rv = ioctl(sock, SIOCGIFCONF, &ifc); if (rv < 0) { if (errno != EINVAL || lastlen != 0) { close(sock); PR_Free(buf); return; } } else { if (ifc.ifc_len == lastlen) { break; /* success, len has not changed */ } lastlen = ifc.ifc_len; } len += 10 * sizeof(struct ifreq); /* increment */ PR_Free(buf); } close(sock); ifr = ifc.ifc_req; lifr = (struct ifreq *)&ifc.ifc_buf[ifc.ifc_len]; while (ifr < lifr) { struct sockaddr *sa; int sa_len; #ifdef DEBUG_QUERY_IFS _pr_PrintIfreq(ifr); #endif sa = &ifr->ifr_addr; if (sa->sa_family == AF_INET) { struct sockaddr_in *sin = (struct sockaddr_in *) sa; if (sin->sin_addr.s_addr != htonl(INADDR_LOOPBACK)) { _pr_have_inet_if = PR_TRUE; } } else if (sa->sa_family == AF_INET6) { struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *) sa; if (!IN6_IS_ADDR_LOOPBACK(&sin6->sin6_addr) && !IN6_IS_ADDR_LINKLOCAL(&sin6->sin6_addr)) { _pr_have_inet6_if = PR_TRUE; } } #ifdef _PR_HAVE_SOCKADDR_LEN sa_len = PR_MAX(sa->sa_len, sizeof(struct sockaddr)); #else switch (sa->sa_family) { #ifdef AF_LINK case AF_LINK: sa_len = sizeof(struct sockaddr_dl); break; #endif case AF_INET6: sa_len = sizeof(struct sockaddr_in6); break; default: sa_len = sizeof(struct sockaddr); break; } #endif ifr = (struct ifreq *)(((char *)sa) + sa_len); } PR_Free(buf); } #elif (defined(DARWIN) && defined(HAVE_GETIFADDRS)) || defined(FREEBSD) \ || defined(NETBSD) || defined(OPENBSD) /* * Use the BSD getifaddrs function. */ #include #include #include #include #ifdef DEBUG_QUERY_IFS static void _pr_PrintIfaddrs(struct ifaddrs *ifa) { struct sockaddr *sa; const char* family; void *addrp; char addrstr[64]; sa = ifa->ifa_addr; if (sa->sa_family == AF_INET) { struct sockaddr_in *sin = (struct sockaddr_in *)sa; family = "inet"; addrp = &sin->sin_addr; } else if (sa->sa_family == AF_INET6) { struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *)sa; family = "inet6"; addrp = &sin6->sin6_addr; } else { return; /* skip if not AF_INET or AF_INET6 */ } inet_ntop(sa->sa_family, addrp, addrstr, sizeof(addrstr)); printf("%s: %s %s\n", ifa->ifa_name, family, addrstr); } #endif static void _pr_QueryNetIfs(void) { struct ifaddrs *ifp; struct ifaddrs *ifa; if (getifaddrs(&ifp) == -1) { return; } for (ifa = ifp; ifa; ifa = ifa->ifa_next) { struct sockaddr *sa; #ifdef DEBUG_QUERY_IFS _pr_PrintIfaddrs(ifa); #endif sa = ifa->ifa_addr; if (sa->sa_family == AF_INET) { struct sockaddr_in *sin = (struct sockaddr_in *) sa; if (sin->sin_addr.s_addr != htonl(INADDR_LOOPBACK)) { _pr_have_inet_if = 1; } } else if (sa->sa_family == AF_INET6) { struct sockaddr_in6 *sin6 = (struct sockaddr_in6 *) sa; if (!IN6_IS_ADDR_LOOPBACK(&sin6->sin6_addr) && !IN6_IS_ADDR_LINKLOCAL(&sin6->sin6_addr)) { _pr_have_inet6_if = 1; } } } freeifaddrs(ifp); } #else /* default */ /* * Emulate the code in NSPR 4.2 or older. PR_GetIPNodeByName behaves * as if the system had both IPv4 and IPv6 source addresses configured. */ static void _pr_QueryNetIfs(void) { _pr_have_inet_if = PR_TRUE; _pr_have_inet6_if = PR_TRUE; } #endif #endif /* _PR_INET6 && _PR_HAVE_GETHOSTBYNAME2 */ void _PR_InitNet(void) { #if defined(XP_UNIX) #ifdef HAVE_NETCONFIG /* * This one-liner prevents the endless re-open's and re-read's of * /etc/netconfig on EACH and EVERY call to accept(), connect(), etc. */ (void)setnetconfig(); #endif #endif #if !defined(_PR_NO_DNS_LOCK) _pr_dnsLock = PR_NewLock(); #endif #if !defined(_PR_HAVE_GETPROTO_R) _getproto_lock = PR_NewLock(); #endif #if defined(_PR_INET6) && defined(_PR_HAVE_GETHOSTBYNAME2) _pr_query_ifs_lock = PR_NewLock(); #endif } void _PR_CleanupNet(void) { #if !defined(_PR_NO_DNS_LOCK) if (_pr_dnsLock) { PR_DestroyLock(_pr_dnsLock); _pr_dnsLock = NULL; } #endif #if !defined(_PR_HAVE_GETPROTO_R) if (_getproto_lock) { PR_DestroyLock(_getproto_lock); _getproto_lock = NULL; } #endif #if defined(_PR_INET6) && defined(_PR_HAVE_GETHOSTBYNAME2) if (_pr_query_ifs_lock) { PR_DestroyLock(_pr_query_ifs_lock); _pr_query_ifs_lock = NULL; } #endif } /* ** Allocate space from the buffer, aligning it to "align" before doing ** the allocation. "align" must be a power of 2. */ static char *Alloc(PRIntn amount, char **bufp, PRIntn *buflenp, PRIntn align) { char *buf = *bufp; PRIntn buflen = *buflenp; if (align && ((long)buf & (align - 1))) { PRIntn skip = align - ((ptrdiff_t)buf & (align - 1)); if (buflen < skip) { return 0; } buf += skip; buflen -= skip; } if (buflen < amount) { return 0; } *bufp = buf + amount; *buflenp = buflen - amount; return buf; } typedef enum _PRIPAddrConversion { _PRIPAddrNoConversion, _PRIPAddrIPv4Mapped, _PRIPAddrIPv4Compat } _PRIPAddrConversion; /* ** Convert an IPv4 address (v4) to an IPv4-mapped IPv6 address (v6). */ static void MakeIPv4MappedAddr(const char *v4, char *v6) { memset(v6, 0, 10); memset(v6 + 10, 0xff, 2); memcpy(v6 + 12, v4, 4); } /* ** Convert an IPv4 address (v4) to an IPv4-compatible IPv6 address (v6). */ static void MakeIPv4CompatAddr(const char *v4, char *v6) { memset(v6, 0, 12); memcpy(v6 + 12, v4, 4); } /* ** Copy a hostent, and all of the memory that it refers to into ** (hopefully) stacked buffers. */ static PRStatus CopyHostent( struct hostent *from, char **buf, PRIntn *bufsize, _PRIPAddrConversion conversion, PRHostEnt *to) { PRIntn len, na; char **ap; if (conversion != _PRIPAddrNoConversion && from->h_addrtype == AF_INET) { PR_ASSERT(from->h_length == 4); to->h_addrtype = PR_AF_INET6; to->h_length = 16; } else { #if defined(_PR_INET6) || defined(_PR_INET6_PROBE) if (AF_INET6 == from->h_addrtype) { to->h_addrtype = PR_AF_INET6; } else #endif to->h_addrtype = from->h_addrtype; to->h_length = from->h_length; } /* Copy the official name */ if (!from->h_name) { return PR_FAILURE; } len = strlen(from->h_name) + 1; to->h_name = Alloc(len, buf, bufsize, 0); if (!to->h_name) { return PR_FAILURE; } memcpy(to->h_name, from->h_name, len); /* Count the aliases, then allocate storage for the pointers */ if (!from->h_aliases) { na = 1; } else { for (na = 1, ap = from->h_aliases; *ap != 0; na++, ap++) {;} /* nothing to execute */ } to->h_aliases = (char**)Alloc( na * sizeof(char*), buf, bufsize, sizeof(char**)); if (!to->h_aliases) { return PR_FAILURE; } /* Copy the aliases, one at a time */ if (!from->h_aliases) { to->h_aliases[0] = 0; } else { for (na = 0, ap = from->h_aliases; *ap != 0; na++, ap++) { len = strlen(*ap) + 1; to->h_aliases[na] = Alloc(len, buf, bufsize, 0); if (!to->h_aliases[na]) { return PR_FAILURE; } memcpy(to->h_aliases[na], *ap, len); } to->h_aliases[na] = 0; } /* Count the addresses, then allocate storage for the pointers */ for (na = 1, ap = from->h_addr_list; *ap != 0; na++, ap++) {;} /* nothing to execute */ to->h_addr_list = (char**)Alloc( na * sizeof(char*), buf, bufsize, sizeof(char**)); if (!to->h_addr_list) { return PR_FAILURE; } /* Copy the addresses, one at a time */ for (na = 0, ap = from->h_addr_list; *ap != 0; na++, ap++) { to->h_addr_list[na] = Alloc(to->h_length, buf, bufsize, 0); if (!to->h_addr_list[na]) { return PR_FAILURE; } if (conversion != _PRIPAddrNoConversion && from->h_addrtype == AF_INET) { if (conversion == _PRIPAddrIPv4Mapped) { MakeIPv4MappedAddr(*ap, to->h_addr_list[na]); } else { PR_ASSERT(conversion == _PRIPAddrIPv4Compat); MakeIPv4CompatAddr(*ap, to->h_addr_list[na]); } } else { memcpy(to->h_addr_list[na], *ap, to->h_length); } } to->h_addr_list[na] = 0; return PR_SUCCESS; } #if !defined(_PR_HAVE_GETPROTO_R) /* ** Copy a protoent, and all of the memory that it refers to into ** (hopefully) stacked buffers. */ static PRStatus CopyProtoent( struct protoent *from, char *buf, PRIntn bufsize, PRProtoEnt *to) { PRIntn len, na; char **ap; /* Do the easy stuff */ to->p_num = from->p_proto; /* Copy the official name */ if (!from->p_name) { return PR_FAILURE; } len = strlen(from->p_name) + 1; to->p_name = Alloc(len, &buf, &bufsize, 0); if (!to->p_name) { return PR_FAILURE; } memcpy(to->p_name, from->p_name, len); /* Count the aliases, then allocate storage for the pointers */ for (na = 1, ap = from->p_aliases; *ap != 0; na++, ap++) {;} /* nothing to execute */ to->p_aliases = (char**)Alloc( na * sizeof(char*), &buf, &bufsize, sizeof(char**)); if (!to->p_aliases) { return PR_FAILURE; } /* Copy the aliases, one at a time */ for (na = 0, ap = from->p_aliases; *ap != 0; na++, ap++) { len = strlen(*ap) + 1; to->p_aliases[na] = Alloc(len, &buf, &bufsize, 0); if (!to->p_aliases[na]) { return PR_FAILURE; } memcpy(to->p_aliases[na], *ap, len); } to->p_aliases[na] = 0; return PR_SUCCESS; } #endif /* !defined(_PR_HAVE_GETPROTO_R) */ /* * ################################################################# * NOTE: tmphe, tmpbuf, bufsize, h, and h_err are local variables * or arguments of PR_GetHostByName, PR_GetIPNodeByName, and * PR_GetHostByAddr. DO NOT CHANGE THE NAMES OF THESE LOCAL * VARIABLES OR ARGUMENTS. * ################################################################# */ #if defined(_PR_HAVE_GETHOST_R_INT) #define GETHOSTBYNAME(name) \ (gethostbyname_r(name, &tmphe, tmpbuf, bufsize, &h, &h_err), h) #define GETHOSTBYNAME2(name, af) \ (gethostbyname2_r(name, af, &tmphe, tmpbuf, bufsize, &h, &h_err), h) #define GETHOSTBYADDR(addr, addrlen, af) \ (gethostbyaddr_r(addr, addrlen, af, \ &tmphe, tmpbuf, bufsize, &h, &h_err), h) #elif defined(_PR_HAVE_GETHOST_R_POINTER) #define GETHOSTBYNAME(name) \ gethostbyname_r(name, &tmphe, tmpbuf, bufsize, &h_err) #define GETHOSTBYNAME2(name, af) \ gethostbyname2_r(name, af, &tmphe, tmpbuf, bufsize, &h_err) #define GETHOSTBYADDR(addr, addrlen, af) \ gethostbyaddr_r(addr, addrlen, af, &tmphe, tmpbuf, bufsize, &h_err) #else #define GETHOSTBYNAME(name) gethostbyname(name) #define GETHOSTBYNAME2(name, af) gethostbyname2(name, af) #define GETHOSTBYADDR(addr, addrlen, af) gethostbyaddr(addr, addrlen, af) #endif /* definition of GETHOSTBYXXX */ PR_IMPLEMENT(PRStatus) PR_GetHostByName( const char *name, char *buf, PRIntn bufsize, PRHostEnt *hp) { struct hostent *h; PRStatus rv = PR_FAILURE; #if defined(_PR_HAVE_GETHOST_R) char localbuf[PR_NETDB_BUF_SIZE]; char *tmpbuf; struct hostent tmphe; int h_err; #endif if (!_pr_initialized) { _PR_ImplicitInitialization(); } #if defined(_PR_HAVE_GETHOST_R) tmpbuf = localbuf; if (bufsize > sizeof(localbuf)) { tmpbuf = (char *)PR_Malloc(bufsize); if (NULL == tmpbuf) { PR_SetError(PR_OUT_OF_MEMORY_ERROR, 0); return rv; } } #endif LOCK_DNS(); h = GETHOSTBYNAME(name); if (NULL == h) { PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_GETHOST_ERRNO()); } else { _PRIPAddrConversion conversion = _PRIPAddrNoConversion; rv = CopyHostent(h, &buf, &bufsize, conversion, hp); if (PR_SUCCESS != rv) { PR_SetError(PR_INSUFFICIENT_RESOURCES_ERROR, 0); } } UNLOCK_DNS(); #if defined(_PR_HAVE_GETHOST_R) if (tmpbuf != localbuf) { PR_Free(tmpbuf); } #endif return rv; } #if !defined(_PR_INET6) && \ defined(_PR_INET6_PROBE) && defined(_PR_HAVE_GETIPNODEBYNAME) typedef struct hostent * (*_pr_getipnodebyname_t)(const char *, int, int, int *); typedef struct hostent * (*_pr_getipnodebyaddr_t)(const void *, size_t, int, int *); typedef void (*_pr_freehostent_t)(struct hostent *); static void * _pr_getipnodebyname_fp; static void * _pr_getipnodebyaddr_fp; static void * _pr_freehostent_fp; /* * Look up the addresses of getipnodebyname, getipnodebyaddr, * and freehostent. */ PRStatus _pr_find_getipnodebyname(void) { PRLibrary *lib; PRStatus rv; #define GETIPNODEBYNAME "getipnodebyname" #define GETIPNODEBYADDR "getipnodebyaddr" #define FREEHOSTENT "freehostent" _pr_getipnodebyname_fp = PR_FindSymbolAndLibrary(GETIPNODEBYNAME, &lib); if (NULL != _pr_getipnodebyname_fp) { _pr_freehostent_fp = PR_FindSymbol(lib, FREEHOSTENT); if (NULL != _pr_freehostent_fp) { _pr_getipnodebyaddr_fp = PR_FindSymbol(lib, GETIPNODEBYADDR); if (NULL != _pr_getipnodebyaddr_fp) { rv = PR_SUCCESS; } else { rv = PR_FAILURE; } } else { rv = PR_FAILURE; } (void)PR_UnloadLibrary(lib); } else { rv = PR_FAILURE; } return rv; } #endif #if defined(_PR_INET6) && defined(_PR_HAVE_GETHOSTBYNAME2) /* ** Append the V4 addresses to the end of the list */ static PRStatus AppendV4AddrsToHostent( struct hostent *from, char **buf, PRIntn *bufsize, PRHostEnt *to) { PRIntn na, na_old; char **ap; char **new_addr_list; /* Count the addresses, then grow storage for the pointers */ for (na_old = 0, ap = to->h_addr_list; *ap != 0; na_old++, ap++) {;} /* nothing to execute */ for (na = na_old + 1, ap = from->h_addr_list; *ap != 0; na++, ap++) {;} /* nothing to execute */ new_addr_list = (char**)Alloc( na * sizeof(char*), buf, bufsize, sizeof(char**)); if (!new_addr_list) { return PR_FAILURE; } /* Copy the V6 addresses, one at a time */ for (na = 0, ap = to->h_addr_list; *ap != 0; na++, ap++) { new_addr_list[na] = to->h_addr_list[na]; } to->h_addr_list = new_addr_list; /* Copy the V4 addresses, one at a time */ for (ap = from->h_addr_list; *ap != 0; na++, ap++) { to->h_addr_list[na] = Alloc(to->h_length, buf, bufsize, 0); if (!to->h_addr_list[na]) { return PR_FAILURE; } MakeIPv4MappedAddr(*ap, to->h_addr_list[na]); } to->h_addr_list[na] = 0; return PR_SUCCESS; } #endif PR_IMPLEMENT(PRStatus) PR_GetIPNodeByName( const char *name, PRUint16 af, PRIntn flags, char *buf, PRIntn bufsize, PRHostEnt *hp) { struct hostent *h = 0; PRStatus rv = PR_FAILURE; #if defined(_PR_HAVE_GETHOST_R) char localbuf[PR_NETDB_BUF_SIZE]; char *tmpbuf; struct hostent tmphe; int h_err; #endif #if defined(_PR_HAVE_GETIPNODEBYNAME) PRUint16 md_af = af; int error_num; int tmp_flags = 0; #endif #if defined(_PR_HAVE_GETHOSTBYNAME2) PRBool did_af_inet = PR_FALSE; #endif if (!_pr_initialized) { _PR_ImplicitInitialization(); } if (af != PR_AF_INET && af != PR_AF_INET6) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); return PR_FAILURE; } #if defined(_PR_INET6) && defined(_PR_HAVE_GETHOSTBYNAME2) PR_Lock(_pr_query_ifs_lock); /* * Keep querying the presence of IPv4 and IPv6 interfaces until * at least one is up. This allows us to detect the local * machine going from offline to online. */ if (!_pr_have_inet_if && !_pr_have_inet6_if) { _pr_QueryNetIfs(); #ifdef DEBUG_QUERY_IFS if (_pr_have_inet_if) { printf("Have IPv4 source address\n"); } if (_pr_have_inet6_if) { printf("Have IPv6 source address\n"); } #endif } PR_Unlock(_pr_query_ifs_lock); #endif #if defined(_PR_HAVE_GETIPNODEBYNAME) if (flags & PR_AI_V4MAPPED) { tmp_flags |= AI_V4MAPPED; } if (flags & PR_AI_ADDRCONFIG) { tmp_flags |= AI_ADDRCONFIG; } if (flags & PR_AI_ALL) { tmp_flags |= AI_ALL; } if (af == PR_AF_INET6) { md_af = AF_INET6; } else { md_af = af; } #endif #if defined(_PR_HAVE_GETHOST_R) tmpbuf = localbuf; if (bufsize > sizeof(localbuf)) { tmpbuf = (char *)PR_Malloc(bufsize); if (NULL == tmpbuf) { PR_SetError(PR_OUT_OF_MEMORY_ERROR, 0); return rv; } } #endif /* Do not need to lock the DNS lock if getipnodebyname() is called */ #ifdef _PR_INET6 #ifdef _PR_HAVE_GETHOSTBYNAME2 LOCK_DNS(); if (af == PR_AF_INET6) { if ((flags & PR_AI_ADDRCONFIG) == 0 || _pr_have_inet6_if) { #ifdef _PR_INET6_PROBE if (_pr_ipv6_is_present()) #endif h = GETHOSTBYNAME2(name, AF_INET6); } if ((NULL == h) && (flags & PR_AI_V4MAPPED) && ((flags & PR_AI_ADDRCONFIG) == 0 || _pr_have_inet_if)) { did_af_inet = PR_TRUE; h = GETHOSTBYNAME2(name, AF_INET); } } else { if ((flags & PR_AI_ADDRCONFIG) == 0 || _pr_have_inet_if) { did_af_inet = PR_TRUE; h = GETHOSTBYNAME2(name, af); } } #elif defined(_PR_HAVE_GETIPNODEBYNAME) h = getipnodebyname(name, md_af, tmp_flags, &error_num); #else #error "Unknown name-to-address translation function" #endif /* _PR_HAVE_GETHOSTBYNAME2 */ #elif defined(_PR_INET6_PROBE) && defined(_PR_HAVE_GETIPNODEBYNAME) if (_pr_ipv6_is_present()) { #ifdef PR_GETIPNODE_NOT_THREADSAFE LOCK_DNS(); #endif h = (*((_pr_getipnodebyname_t)_pr_getipnodebyname_fp))(name, md_af, tmp_flags, &error_num); } else { LOCK_DNS(); h = GETHOSTBYNAME(name); } #else /* _PR_INET6 */ LOCK_DNS(); h = GETHOSTBYNAME(name); #endif /* _PR_INET6 */ if (NULL == h) { #if defined(_PR_INET6) && defined(_PR_HAVE_GETIPNODEBYNAME) PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, error_num); #elif defined(_PR_INET6_PROBE) && defined(_PR_HAVE_GETIPNODEBYNAME) if (_pr_ipv6_is_present()) { PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, error_num); } else { PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_GETHOST_ERRNO()); } #else PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_GETHOST_ERRNO()); #endif } else { _PRIPAddrConversion conversion = _PRIPAddrNoConversion; if (af == PR_AF_INET6) { conversion = _PRIPAddrIPv4Mapped; } rv = CopyHostent(h, &buf, &bufsize, conversion, hp); if (PR_SUCCESS != rv) { PR_SetError(PR_INSUFFICIENT_RESOURCES_ERROR, 0); } #if defined(_PR_INET6) && defined(_PR_HAVE_GETIPNODEBYNAME) freehostent(h); #elif defined(_PR_INET6_PROBE) && defined(_PR_HAVE_GETIPNODEBYNAME) if (_pr_ipv6_is_present()) { (*((_pr_freehostent_t)_pr_freehostent_fp))(h); } #endif #if defined(_PR_INET6) && defined(_PR_HAVE_GETHOSTBYNAME2) if ((PR_SUCCESS == rv) && (flags & PR_AI_V4MAPPED) && ((flags & PR_AI_ALL) || ((flags & PR_AI_ADDRCONFIG) && _pr_have_inet_if)) && !did_af_inet && (h = GETHOSTBYNAME2(name, AF_INET)) != 0) { rv = AppendV4AddrsToHostent(h, &buf, &bufsize, hp); if (PR_SUCCESS != rv) { PR_SetError(PR_INSUFFICIENT_RESOURCES_ERROR, 0); } } #endif } /* Must match the convoluted logic above for LOCK_DNS() */ #ifdef _PR_INET6 #ifdef _PR_HAVE_GETHOSTBYNAME2 UNLOCK_DNS(); #endif /* _PR_HAVE_GETHOSTBYNAME2 */ #elif defined(_PR_INET6_PROBE) && defined(_PR_HAVE_GETIPNODEBYNAME) #ifdef PR_GETIPNODE_NOT_THREADSAFE UNLOCK_DNS(); #else if (!_pr_ipv6_is_present()) { UNLOCK_DNS(); } #endif #else /* _PR_INET6 */ UNLOCK_DNS(); #endif /* _PR_INET6 */ #if defined(_PR_HAVE_GETHOST_R) if (tmpbuf != localbuf) { PR_Free(tmpbuf); } #endif return rv; } PR_IMPLEMENT(PRStatus) PR_GetHostByAddr( const PRNetAddr *hostaddr, char *buf, PRIntn bufsize, PRHostEnt *hostentry) { struct hostent *h; PRStatus rv = PR_FAILURE; const void *addr; PRUint32 tmp_ip; int addrlen; PRInt32 af; #if defined(_PR_HAVE_GETHOST_R) char localbuf[PR_NETDB_BUF_SIZE]; char *tmpbuf; struct hostent tmphe; int h_err; #endif #if defined(_PR_HAVE_GETIPNODEBYADDR) int error_num; #endif if (!_pr_initialized) { _PR_ImplicitInitialization(); } if (hostaddr->raw.family == PR_AF_INET6) { #if defined(_PR_INET6_PROBE) af = _pr_ipv6_is_present() ? AF_INET6 : AF_INET; #elif defined(_PR_INET6) af = AF_INET6; #else af = AF_INET; #endif #if defined(_PR_GHBA_DISALLOW_V4MAPPED) if (_PR_IN6_IS_ADDR_V4MAPPED(&hostaddr->ipv6.ip)) { af = AF_INET; } #endif } else { PR_ASSERT(hostaddr->raw.family == AF_INET); af = AF_INET; } if (hostaddr->raw.family == PR_AF_INET6) { #if defined(_PR_INET6) || defined(_PR_INET6_PROBE) if (af == AF_INET6) { addr = &hostaddr->ipv6.ip; addrlen = sizeof(hostaddr->ipv6.ip); } else #endif { PR_ASSERT(af == AF_INET); if (!_PR_IN6_IS_ADDR_V4MAPPED(&hostaddr->ipv6.ip)) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); return rv; } tmp_ip = _PR_IN6_V4MAPPED_TO_IPADDR((PRIPv6Addr *) &hostaddr->ipv6.ip); addr = &tmp_ip; addrlen = sizeof(tmp_ip); } } else { PR_ASSERT(hostaddr->raw.family == AF_INET); PR_ASSERT(af == AF_INET); addr = &hostaddr->inet.ip; addrlen = sizeof(hostaddr->inet.ip); } #if defined(_PR_HAVE_GETHOST_R) tmpbuf = localbuf; if (bufsize > sizeof(localbuf)) { tmpbuf = (char *)PR_Malloc(bufsize); if (NULL == tmpbuf) { PR_SetError(PR_OUT_OF_MEMORY_ERROR, 0); return rv; } } #endif /* Do not need to lock the DNS lock if getipnodebyaddr() is called */ #if defined(_PR_HAVE_GETIPNODEBYADDR) && defined(_PR_INET6) h = getipnodebyaddr(addr, addrlen, af, &error_num); #elif defined(_PR_HAVE_GETIPNODEBYADDR) && defined(_PR_INET6_PROBE) if (_pr_ipv6_is_present()) { #ifdef PR_GETIPNODE_NOT_THREADSAFE LOCK_DNS(); #endif h = (*((_pr_getipnodebyaddr_t)_pr_getipnodebyaddr_fp))(addr, addrlen, af, &error_num); } else { LOCK_DNS(); h = GETHOSTBYADDR(addr, addrlen, af); } #else /* _PR_HAVE_GETIPNODEBYADDR */ LOCK_DNS(); h = GETHOSTBYADDR(addr, addrlen, af); #endif /* _PR_HAVE_GETIPNODEBYADDR */ if (NULL == h) { #if defined(_PR_INET6) && defined(_PR_HAVE_GETIPNODEBYADDR) PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, error_num); #elif defined(_PR_INET6_PROBE) && defined(_PR_HAVE_GETIPNODEBYADDR) if (_pr_ipv6_is_present()) { PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, error_num); } else { PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_GETHOST_ERRNO()); } #else PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_GETHOST_ERRNO()); #endif } else { _PRIPAddrConversion conversion = _PRIPAddrNoConversion; if (hostaddr->raw.family == PR_AF_INET6) { if (af == AF_INET) { if (_PR_IN6_IS_ADDR_V4MAPPED((PRIPv6Addr*) &hostaddr->ipv6.ip)) { conversion = _PRIPAddrIPv4Mapped; } else if (_PR_IN6_IS_ADDR_V4COMPAT((PRIPv6Addr *) &hostaddr->ipv6.ip)) { conversion = _PRIPAddrIPv4Compat; } } } rv = CopyHostent(h, &buf, &bufsize, conversion, hostentry); if (PR_SUCCESS != rv) { PR_SetError(PR_INSUFFICIENT_RESOURCES_ERROR, 0); } #if defined(_PR_INET6) && defined(_PR_HAVE_GETIPNODEBYADDR) freehostent(h); #elif defined(_PR_INET6_PROBE) && defined(_PR_HAVE_GETIPNODEBYADDR) if (_pr_ipv6_is_present()) { (*((_pr_freehostent_t)_pr_freehostent_fp))(h); } #endif } /* Must match the convoluted logic above for LOCK_DNS() */ #if defined(_PR_HAVE_GETIPNODEBYADDR) && defined(_PR_INET6) #elif defined(_PR_HAVE_GETIPNODEBYADDR) && defined(_PR_INET6_PROBE) #ifdef PR_GETIPNODE_NOT_THREADSAFE UNLOCK_DNS(); #else if (!_pr_ipv6_is_present()) { UNLOCK_DNS(); } #endif #else /* _PR_HAVE_GETIPNODEBYADDR */ UNLOCK_DNS(); #endif /* _PR_HAVE_GETIPNODEBYADDR */ #if defined(_PR_HAVE_GETHOST_R) if (tmpbuf != localbuf) { PR_Free(tmpbuf); } #endif return rv; } /******************************************************************************/ /* * Some systems define a reentrant version of getprotobyname(). Too bad * the signature isn't always the same. But hey, they tried. If there * is such a definition, use it. Otherwise, grab a lock and do it here. */ /******************************************************************************/ #if !defined(_PR_HAVE_GETPROTO_R) /* * This may seem like a silly thing to do, but the compiler SHOULD * complain if getprotobyname_r() is implemented on some system and * we're not using it. For sure these signatures are different than * any usable implementation. */ #if defined(ANDROID) /* Android's Bionic libc system includes prototypes for these in netdb.h, * but doesn't actually include implementations. It uses the 5-arg form, * so these functions end up not matching the prototype. So just rename * them if not found. */ #define getprotobyname_r _pr_getprotobyname_r #define getprotobynumber_r _pr_getprotobynumber_r #endif static struct protoent *getprotobyname_r(const char* name) { return getprotobyname(name); } /* getprotobyname_r */ static struct protoent *getprotobynumber_r(PRInt32 number) { return getprotobynumber(number); } /* getprotobynumber_r */ #endif /* !defined(_PR_HAVE_GETPROTO_R) */ PR_IMPLEMENT(PRStatus) PR_GetProtoByName( const char* name, char* buffer, PRInt32 buflen, PRProtoEnt* result) { PRStatus rv = PR_SUCCESS; #if defined(_PR_HAVE_GETPROTO_R) struct protoent* res = (struct protoent*)result; #endif if (!_pr_initialized) { _PR_ImplicitInitialization(); } #if defined(_PR_HAVE_GETPROTO_R_INT) { /* ** The protoent_data has a pointer as the first field. ** That implies the buffer better be aligned, and char* ** doesn't promise much. */ PRUptrdiff aligned = (PRUptrdiff)buffer; if (0 != (aligned & (sizeof(struct protoent_data*) - 1))) { aligned += sizeof(struct protoent_data*) - 1; aligned &= ~(sizeof(struct protoent_data*) - 1); buflen -= (aligned - (PRUptrdiff)buffer); buffer = (char*)aligned; } } #endif /* defined(_PR_HAVE_GETPROTO_R_INT) */ if (PR_NETDB_BUF_SIZE > buflen) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); return PR_FAILURE; } #if defined(_PR_HAVE_GETPROTO_R_POINTER) if (NULL == getprotobyname_r(name, res, buffer, buflen)) { PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_ERRNO()); return PR_FAILURE; } #elif defined(_PR_HAVE_GETPROTO_R_INT) /* ** The buffer needs to be zero'd, and it should be ** at least the size of a struct protoent_data. */ memset(buffer, 0, buflen); if (-1 == getprotobyname_r(name, res, (struct protoent_data*)buffer)) { PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_ERRNO()); return PR_FAILURE; } #elif defined(_PR_HAVE_5_ARG_GETPROTO_R) /* The 5th argument for getprotobyname_r() cannot be NULL */ if (-1 == getprotobyname_r(name, res, buffer, buflen, &res)) { PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_ERRNO()); return PR_FAILURE; } #else /* do it the hard way */ { struct protoent *staticBuf; PR_Lock(_getproto_lock); staticBuf = getprotobyname_r(name); if (NULL == staticBuf) { rv = PR_FAILURE; PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_ERRNO()); } else { rv = CopyProtoent(staticBuf, buffer, buflen, result); if (PR_FAILURE == rv) { PR_SetError(PR_INSUFFICIENT_RESOURCES_ERROR, 0); } } PR_Unlock(_getproto_lock); } #endif /* all that */ return rv; } PR_IMPLEMENT(PRStatus) PR_GetProtoByNumber( PRInt32 number, char* buffer, PRInt32 buflen, PRProtoEnt* result) { PRStatus rv = PR_SUCCESS; #if defined(_PR_HAVE_GETPROTO_R) struct protoent* res = (struct protoent*)result; #endif if (!_pr_initialized) { _PR_ImplicitInitialization(); } #if defined(_PR_HAVE_GETPROTO_R_INT) { /* ** The protoent_data has a pointer as the first field. ** That implies the buffer better be aligned, and char* ** doesn't promise much. */ PRUptrdiff aligned = (PRUptrdiff)buffer; if (0 != (aligned & (sizeof(struct protoent_data*) - 1))) { aligned += sizeof(struct protoent_data*) - 1; aligned &= ~(sizeof(struct protoent_data*) - 1); buflen -= (aligned - (PRUptrdiff)buffer); buffer = (char*)aligned; } } #endif /* defined(_PR_HAVE_GETPROTO_R_INT) */ if (PR_NETDB_BUF_SIZE > buflen) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); return PR_FAILURE; } #if defined(_PR_HAVE_GETPROTO_R_POINTER) if (NULL == getprotobynumber_r(number, res, buffer, buflen)) { PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_ERRNO()); return PR_FAILURE; } #elif defined(_PR_HAVE_GETPROTO_R_INT) /* ** The buffer needs to be zero'd for these OS's. */ memset(buffer, 0, buflen); if (-1 == getprotobynumber_r(number, res, (struct protoent_data*)buffer)) { PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_ERRNO()); return PR_FAILURE; } #elif defined(_PR_HAVE_5_ARG_GETPROTO_R) /* The 5th argument for getprotobynumber_r() cannot be NULL */ if (-1 == getprotobynumber_r(number, res, buffer, buflen, &res)) { PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_ERRNO()); return PR_FAILURE; } #else /* do it the hard way */ { struct protoent *staticBuf; PR_Lock(_getproto_lock); staticBuf = getprotobynumber_r(number); if (NULL == staticBuf) { rv = PR_FAILURE; PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, _MD_ERRNO()); } else { rv = CopyProtoent(staticBuf, buffer, buflen, result); if (PR_FAILURE == rv) { PR_SetError(PR_INSUFFICIENT_RESOURCES_ERROR, 0); } } PR_Unlock(_getproto_lock); } #endif /* all that crap */ return rv; } PRUintn _PR_NetAddrSize(const PRNetAddr* addr) { PRUintn addrsize; /* * RFC 2553 added a new field (sin6_scope_id) to * struct sockaddr_in6. PRNetAddr's ipv6 member has a * scope_id field to match the new field. In order to * work with older implementations supporting RFC 2133, * we take the size of struct sockaddr_in6 instead of * addr->ipv6. */ if (AF_INET == addr->raw.family) { addrsize = sizeof(addr->inet); } else if (PR_AF_INET6 == addr->raw.family) #if defined(_PR_INET6) addrsize = sizeof(struct sockaddr_in6); #else addrsize = sizeof(addr->ipv6); #endif #if defined(XP_UNIX) || defined(XP_OS2) else if (AF_UNIX == addr->raw.family) { #if defined(LINUX) if (addr->local.path[0] == 0) /* abstract socket address is supported on Linux only */ addrsize = strnlen(addr->local.path + 1, sizeof(addr->local.path)) + offsetof(struct sockaddr_un, sun_path) + 1; else #endif addrsize = sizeof(addr->local); } #endif else { addrsize = 0; } return addrsize; } /* _PR_NetAddrSize */ PR_IMPLEMENT(PRIntn) PR_EnumerateHostEnt( PRIntn enumIndex, const PRHostEnt *hostEnt, PRUint16 port, PRNetAddr *address) { void *addr = hostEnt->h_addr_list[enumIndex++]; memset(address, 0, sizeof(PRNetAddr)); if (NULL == addr) { enumIndex = 0; } else { address->raw.family = hostEnt->h_addrtype; if (PR_AF_INET6 == hostEnt->h_addrtype) { address->ipv6.port = htons(port); address->ipv6.flowinfo = 0; address->ipv6.scope_id = 0; memcpy(&address->ipv6.ip, addr, hostEnt->h_length); } else { PR_ASSERT(AF_INET == hostEnt->h_addrtype); address->inet.port = htons(port); memcpy(&address->inet.ip, addr, hostEnt->h_length); } } return enumIndex; } /* PR_EnumerateHostEnt */ PR_IMPLEMENT(PRStatus) PR_InitializeNetAddr( PRNetAddrValue val, PRUint16 port, PRNetAddr *addr) { PRStatus rv = PR_SUCCESS; if (!_pr_initialized) { _PR_ImplicitInitialization(); } if (val != PR_IpAddrNull) { memset(addr, 0, sizeof(*addr)); } addr->inet.family = AF_INET; addr->inet.port = htons(port); switch (val) { case PR_IpAddrNull: break; /* don't overwrite the address */ case PR_IpAddrAny: addr->inet.ip = htonl(INADDR_ANY); break; case PR_IpAddrLoopback: addr->inet.ip = htonl(INADDR_LOOPBACK); break; default: PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); rv = PR_FAILURE; } return rv; } /* PR_InitializeNetAddr */ PR_IMPLEMENT(PRStatus) PR_SetNetAddr( PRNetAddrValue val, PRUint16 af, PRUint16 port, PRNetAddr *addr) { PRStatus rv = PR_SUCCESS; if (!_pr_initialized) { _PR_ImplicitInitialization(); } if (af == PR_AF_INET6) { if (val != PR_IpAddrNull) { memset(addr, 0, sizeof(addr->ipv6)); } addr->ipv6.family = af; addr->ipv6.port = htons(port); addr->ipv6.flowinfo = 0; addr->ipv6.scope_id = 0; switch (val) { case PR_IpAddrNull: break; /* don't overwrite the address */ case PR_IpAddrAny: addr->ipv6.ip = _pr_in6addr_any; break; case PR_IpAddrLoopback: addr->ipv6.ip = _pr_in6addr_loopback; break; default: PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); rv = PR_FAILURE; } } else { if (val != PR_IpAddrNull) { memset(addr, 0, sizeof(addr->inet)); } addr->inet.family = af; addr->inet.port = htons(port); switch (val) { case PR_IpAddrNull: break; /* don't overwrite the address */ case PR_IpAddrAny: addr->inet.ip = htonl(INADDR_ANY); break; case PR_IpAddrLoopback: addr->inet.ip = htonl(INADDR_LOOPBACK); break; default: PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); rv = PR_FAILURE; } } return rv; } /* PR_SetNetAddr */ PR_IMPLEMENT(PRBool) PR_IsNetAddrType(const PRNetAddr *addr, PRNetAddrValue val) { if (addr->raw.family == PR_AF_INET6) { if (val == PR_IpAddrAny) { if (_PR_IN6_IS_ADDR_UNSPECIFIED((PRIPv6Addr *)&addr->ipv6.ip)) { return PR_TRUE; } if (_PR_IN6_IS_ADDR_V4MAPPED((PRIPv6Addr *)&addr->ipv6.ip) && _PR_IN6_V4MAPPED_TO_IPADDR((PRIPv6Addr *)&addr->ipv6.ip) == htonl(INADDR_ANY)) { return PR_TRUE; } } else if (val == PR_IpAddrLoopback) { if (_PR_IN6_IS_ADDR_LOOPBACK((PRIPv6Addr *)&addr->ipv6.ip)) { return PR_TRUE; } if (_PR_IN6_IS_ADDR_V4MAPPED((PRIPv6Addr *)&addr->ipv6.ip) && _PR_IN6_V4MAPPED_TO_IPADDR((PRIPv6Addr *)&addr->ipv6.ip) == htonl(INADDR_LOOPBACK)) { return PR_TRUE; } } else if (val == PR_IpAddrV4Mapped && _PR_IN6_IS_ADDR_V4MAPPED((PRIPv6Addr *)&addr->ipv6.ip)) { return PR_TRUE; } } else { if (addr->raw.family == AF_INET) { if (val == PR_IpAddrAny && addr->inet.ip == htonl(INADDR_ANY)) { return PR_TRUE; } if (val == PR_IpAddrLoopback && addr->inet.ip == htonl(INADDR_LOOPBACK)) { return PR_TRUE; } } } return PR_FALSE; } extern int pr_inet_aton(const char *cp, PRUint32 *addr); #define XX 127 static const unsigned char index_hex[256] = { XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, 0, 1, 2, 3, 4, 5, 6, 7, 8, 9,XX,XX, XX,XX,XX,XX, XX,10,11,12, 13,14,15,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,10,11,12, 13,14,15,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, XX,XX,XX,XX, }; /* * StringToV6Addr() returns 1 if the conversion succeeds, * or 0 if the input is not a valid IPv6 address string. * (Same as inet_pton(AF_INET6, string, addr).) */ static int StringToV6Addr(const char *string, PRIPv6Addr *addr) { const unsigned char *s = (const unsigned char *)string; int section = 0; /* index of the current section (a 16-bit * piece of the address */ int double_colon = -1; /* index of the section after the first * 16-bit group of zeros represented by * the double colon */ unsigned int val; int len; /* Handle initial (double) colon */ if (*s == ':') { if (s[1] != ':') { return 0; } s += 2; addr->pr_s6_addr16[0] = 0; section = double_colon = 1; } while (*s) { if (section == 8) { return 0; /* too long */ } if (*s == ':') { if (double_colon != -1) { return 0; /* two double colons */ } addr->pr_s6_addr16[section++] = 0; double_colon = section; s++; continue; } for (len = val = 0; len < 4 && index_hex[*s] != XX; len++) { val = (val << 4) + index_hex[*s++]; } if (*s == '.') { if (len == 0) { return 0; /* nothing between : and . */ } break; } if (*s == ':') { s++; if (!*s) { return 0; /* cannot end with single colon */ } } else if (*s) { return 0; /* bad character */ } addr->pr_s6_addr16[section++] = htons((unsigned short)val); } if (*s == '.') { /* Have a trailing v4 format address */ if (section > 6) { return 0; /* not enough room */ } /* * The number before the '.' is decimal, but we parsed it * as hex. That means it is in BCD. Check it for validity * and convert it to binary. */ if (val > 0x0255 || (val & 0xf0) > 0x90 || (val & 0xf) > 9) { return 0; } val = (val >> 8) * 100 + ((val >> 4) & 0xf) * 10 + (val & 0xf); addr->pr_s6_addr[2 * section] = val; s++; val = index_hex[*s++]; if (val > 9) { return 0; } while (*s >= '0' && *s <= '9') { val = val * 10 + *s++ - '0'; if (val > 255) { return 0; } } if (*s != '.') { return 0; /* must have exactly 4 decimal numbers */ } addr->pr_s6_addr[2 * section + 1] = val; section++; s++; val = index_hex[*s++]; if (val > 9) { return 0; } while (*s >= '0' && *s <= '9') { val = val * 10 + *s++ - '0'; if (val > 255) { return 0; } } if (*s != '.') { return 0; /* must have exactly 4 decimal numbers */ } addr->pr_s6_addr[2 * section] = val; s++; val = index_hex[*s++]; if (val > 9) { return 0; } while (*s >= '0' && *s <= '9') { val = val * 10 + *s++ - '0'; if (val > 255) { return 0; } } if (*s) { return 0; /* must have exactly 4 decimal numbers */ } addr->pr_s6_addr[2 * section + 1] = val; section++; } if (double_colon != -1) { /* Stretch the double colon */ int tosection; int ncopy = section - double_colon; for (tosection = 7; ncopy--; tosection--) { addr->pr_s6_addr16[tosection] = addr->pr_s6_addr16[double_colon + ncopy]; } while (tosection >= double_colon) { addr->pr_s6_addr16[tosection--] = 0; } } else if (section != 8) { return 0; /* too short */ } return 1; } #undef XX #ifndef _PR_HAVE_INET_NTOP static const char *basis_hex = "0123456789abcdef"; /* * V6AddrToString() returns a pointer to the buffer containing * the text string if the conversion succeeds, and NULL otherwise. * (Same as inet_ntop(AF_INET6, addr, buf, size), except that errno * is not set on failure.) */ static const char *V6AddrToString( const PRIPv6Addr *addr, char *buf, PRUint32 size) { #define STUFF(c) do { \ if (!size--) return NULL; \ *buf++ = (c); \ } while (0) int double_colon = -1; /* index of the first 16-bit * group of zeros represented * by the double colon */ int double_colon_length = 1; /* use double colon only if * there are two or more 16-bit * groups of zeros */ int zero_length; int section; unsigned int val; const char *bufcopy = buf; /* Scan to find the placement of the double colon */ for (section = 0; section < 8; section++) { if (addr->pr_s6_addr16[section] == 0) { zero_length = 1; section++; while (section < 8 && addr->pr_s6_addr16[section] == 0) { zero_length++; section++; } /* Select the longest sequence of zeros */ if (zero_length > double_colon_length) { double_colon = section - zero_length; double_colon_length = zero_length; } } } /* Now start converting to a string */ section = 0; if (double_colon == 0) { if (double_colon_length == 6 || (double_colon_length == 5 && addr->pr_s6_addr16[5] == 0xffff)) { /* ipv4 format address */ STUFF(':'); STUFF(':'); if (double_colon_length == 5) { STUFF('f'); STUFF('f'); STUFF('f'); STUFF('f'); STUFF(':'); } if (addr->pr_s6_addr[12] > 99) { STUFF(addr->pr_s6_addr[12]/100 + '0'); } if (addr->pr_s6_addr[12] > 9) { STUFF((addr->pr_s6_addr[12]%100)/10 + '0'); } STUFF(addr->pr_s6_addr[12]%10 + '0'); STUFF('.'); if (addr->pr_s6_addr[13] > 99) { STUFF(addr->pr_s6_addr[13]/100 + '0'); } if (addr->pr_s6_addr[13] > 9) { STUFF((addr->pr_s6_addr[13]%100)/10 + '0'); } STUFF(addr->pr_s6_addr[13]%10 + '0'); STUFF('.'); if (addr->pr_s6_addr[14] > 99) { STUFF(addr->pr_s6_addr[14]/100 + '0'); } if (addr->pr_s6_addr[14] > 9) { STUFF((addr->pr_s6_addr[14]%100)/10 + '0'); } STUFF(addr->pr_s6_addr[14]%10 + '0'); STUFF('.'); if (addr->pr_s6_addr[15] > 99) { STUFF(addr->pr_s6_addr[15]/100 + '0'); } if (addr->pr_s6_addr[15] > 9) { STUFF((addr->pr_s6_addr[15]%100)/10 + '0'); } STUFF(addr->pr_s6_addr[15]%10 + '0'); STUFF('\0'); return bufcopy; } } while (section < 8) { if (section == double_colon) { STUFF(':'); STUFF(':'); section += double_colon_length; continue; } val = ntohs(addr->pr_s6_addr16[section]); if (val > 0xfff) { STUFF(basis_hex[val >> 12]); } if (val > 0xff) { STUFF(basis_hex[(val >> 8) & 0xf]); } if (val > 0xf) { STUFF(basis_hex[(val >> 4) & 0xf]); } STUFF(basis_hex[val & 0xf]); section++; if (section < 8 && section != double_colon) { STUFF(':'); } } STUFF('\0'); return bufcopy; #undef STUFF } #endif /* !_PR_HAVE_INET_NTOP */ /* * Convert an IPv4 addr to an (IPv4-mapped) IPv6 addr */ PR_IMPLEMENT(void) PR_ConvertIPv4AddrToIPv6(PRUint32 v4addr, PRIPv6Addr *v6addr) { PRUint8 *dstp; dstp = v6addr->pr_s6_addr; memset(dstp, 0, 10); memset(dstp + 10, 0xff, 2); memcpy(dstp + 12,(char *) &v4addr, 4); } PR_IMPLEMENT(PRUint16) PR_ntohs(PRUint16 n) { return ntohs(n); } PR_IMPLEMENT(PRUint32) PR_ntohl(PRUint32 n) { return ntohl(n); } PR_IMPLEMENT(PRUint16) PR_htons(PRUint16 n) { return htons(n); } PR_IMPLEMENT(PRUint32) PR_htonl(PRUint32 n) { return htonl(n); } PR_IMPLEMENT(PRUint64) PR_ntohll(PRUint64 n) { #ifdef IS_BIG_ENDIAN return n; #else PRUint32 hi, lo; lo = (PRUint32)n; hi = (PRUint32)(n >> 32); hi = PR_ntohl(hi); lo = PR_ntohl(lo); return ((PRUint64)lo << 32) + (PRUint64)hi; #endif } /* ntohll */ PR_IMPLEMENT(PRUint64) PR_htonll(PRUint64 n) { #ifdef IS_BIG_ENDIAN return n; #else PRUint32 hi, lo; lo = (PRUint32)n; hi = (PRUint32)(n >> 32); hi = htonl(hi); lo = htonl(lo); return ((PRUint64)lo << 32) + (PRUint64)hi; #endif } /* htonll */ /* * Implementation of PR_GetAddrInfoByName and friends * * Compile-time options: * * _PR_HAVE_GETADDRINFO Define this macro if the target system provides * getaddrinfo. With this defined, NSPR will require * getaddrinfo at run time. If this if not defined, * then NSPR will attempt to dynamically resolve * getaddrinfo, falling back to PR_GetHostByName if * getaddrinfo does not exist on the target system. * * Since getaddrinfo is a relatively new system call on many systems, * we are forced to dynamically resolve it at run time in most cases. * The exception includes any system (such as Mac OS X) that is known to * provide getaddrinfo in all versions that NSPR cares to support. */ #if defined(_PR_HAVE_GETADDRINFO) #if defined(_PR_INET6) typedef struct addrinfo PRADDRINFO; #define GETADDRINFO getaddrinfo #define FREEADDRINFO freeaddrinfo #define GETNAMEINFO getnameinfo #elif defined(_PR_INET6_PROBE) typedef struct addrinfo PRADDRINFO; /* getaddrinfo/freeaddrinfo/getnameinfo prototypes */ #if defined(WIN32) #define FUNC_MODIFIER __stdcall #else #define FUNC_MODIFIER #endif typedef int (FUNC_MODIFIER * FN_GETADDRINFO) (const char *nodename, const char *servname, const PRADDRINFO *hints, PRADDRINFO **res); typedef int (FUNC_MODIFIER * FN_FREEADDRINFO) (PRADDRINFO *ai); typedef int (FUNC_MODIFIER * FN_GETNAMEINFO) (const struct sockaddr *addr, int addrlen, char *host, int hostlen, char *serv, int servlen, int flags); /* global state */ static FN_GETADDRINFO _pr_getaddrinfo = NULL; static FN_FREEADDRINFO _pr_freeaddrinfo = NULL; static FN_GETNAMEINFO _pr_getnameinfo = NULL; #define GETADDRINFO_SYMBOL "getaddrinfo" #define FREEADDRINFO_SYMBOL "freeaddrinfo" #define GETNAMEINFO_SYMBOL "getnameinfo" PRStatus _pr_find_getaddrinfo(void) { PRLibrary *lib; #ifdef WIN32 /* * On windows, we need to search ws2_32.dll or wship6.dll * (Microsoft IPv6 Technology Preview for Windows 2000) for * getaddrinfo and freeaddrinfo. These libraries might not * be loaded yet. */ const char *libname[] = { "ws2_32.dll", "wship6.dll" }; int i; for (i = 0; i < sizeof(libname)/sizeof(libname[0]); i++) { lib = PR_LoadLibrary(libname[i]); if (!lib) { continue; } _pr_getaddrinfo = (FN_GETADDRINFO) PR_FindFunctionSymbol(lib, GETADDRINFO_SYMBOL); if (!_pr_getaddrinfo) { PR_UnloadLibrary(lib); continue; } _pr_freeaddrinfo = (FN_FREEADDRINFO) PR_FindFunctionSymbol(lib, FREEADDRINFO_SYMBOL); _pr_getnameinfo = (FN_GETNAMEINFO) PR_FindFunctionSymbol(lib, GETNAMEINFO_SYMBOL); if (!_pr_freeaddrinfo || !_pr_getnameinfo) { PR_UnloadLibrary(lib); continue; } /* Keep the library loaded. */ return PR_SUCCESS; } return PR_FAILURE; #else /* * Resolve getaddrinfo by searching all loaded libraries. Then * search library containing getaddrinfo for freeaddrinfo. */ _pr_getaddrinfo = (FN_GETADDRINFO) PR_FindFunctionSymbolAndLibrary(GETADDRINFO_SYMBOL, &lib); if (!_pr_getaddrinfo) { return PR_FAILURE; } _pr_freeaddrinfo = (FN_FREEADDRINFO) PR_FindFunctionSymbol(lib, FREEADDRINFO_SYMBOL); _pr_getnameinfo = (FN_GETNAMEINFO) PR_FindFunctionSymbol(lib, GETNAMEINFO_SYMBOL); PR_UnloadLibrary(lib); if (!_pr_freeaddrinfo || !_pr_getnameinfo) { return PR_FAILURE; } return PR_SUCCESS; #endif } #define GETADDRINFO (*_pr_getaddrinfo) #define FREEADDRINFO (*_pr_freeaddrinfo) #define GETNAMEINFO (*_pr_getnameinfo) #endif /* _PR_INET6 */ #endif /* _PR_HAVE_GETADDRINFO */ #if !defined(_PR_HAVE_GETADDRINFO) || defined(_PR_INET6_PROBE) /* * If getaddrinfo does not exist, then we will fall back on * PR_GetHostByName, which requires that we allocate a buffer for the * PRHostEnt data structure and its members. */ typedef struct PRAddrInfoFB { char buf[PR_NETDB_BUF_SIZE]; PRHostEnt hostent; PRBool has_cname; } PRAddrInfoFB; static PRAddrInfo * pr_GetAddrInfoByNameFB(const char *hostname, PRUint16 af, PRIntn flags) { PRStatus rv; PRAddrInfoFB *ai; /* fallback on PR_GetHostByName */ ai = PR_NEW(PRAddrInfoFB); if (!ai) { PR_SetError(PR_OUT_OF_MEMORY_ERROR, 0); return NULL; } rv = PR_GetHostByName(hostname, ai->buf, sizeof ai->buf, &ai->hostent); if (rv == PR_FAILURE) { PR_Free(ai); return NULL; } ai->has_cname = !(flags & PR_AI_NOCANONNAME); return (PRAddrInfo *) ai; } #endif /* !_PR_HAVE_GETADDRINFO || _PR_INET6_PROBE */ PR_IMPLEMENT(PRAddrInfo *) PR_GetAddrInfoByName(const char *hostname, PRUint16 af, PRIntn flags) { /* restrict input to supported values */ if ((af != PR_AF_INET && af != PR_AF_UNSPEC) || (flags & ~ PR_AI_NOCANONNAME) != PR_AI_ADDRCONFIG) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); return NULL; } if (!_pr_initialized) { _PR_ImplicitInitialization(); } #if !defined(_PR_HAVE_GETADDRINFO) return pr_GetAddrInfoByNameFB(hostname, af, flags); #else #if defined(_PR_INET6_PROBE) if (!_pr_ipv6_is_present()) { return pr_GetAddrInfoByNameFB(hostname, af, flags); } #endif { PRADDRINFO *res, hints; int rv; /* * we assume a RFC 2553 compliant getaddrinfo. this may at some * point need to be customized as platforms begin to adopt the * RFC 3493. */ memset(&hints, 0, sizeof(hints)); if (!(flags & PR_AI_NOCANONNAME)) { hints.ai_flags |= AI_CANONNAME; } #ifdef AI_ADDRCONFIG /* * Propagate AI_ADDRCONFIG to the GETADDRINFO call if PR_AI_ADDRCONFIG * is set. * * Need a workaround for loopback host addresses: * The problem is that in glibc and Windows, AI_ADDRCONFIG applies the * existence of an outgoing network interface to IP addresses of the * loopback interface, due to a strict interpretation of the * specification. For example, if a computer does not have any * outgoing IPv6 network interface, but its loopback network interface * supports IPv6, a getaddrinfo call on "localhost" with AI_ADDRCONFIG * won't return the IPv6 loopback address "::1", because getaddrinfo * thinks the computer cannot connect to any IPv6 destination, * ignoring the remote vs. local/loopback distinction. */ if ((flags & PR_AI_ADDRCONFIG) && strcmp(hostname, "localhost") != 0 && strcmp(hostname, "localhost.localdomain") != 0 && strcmp(hostname, "localhost6") != 0 && strcmp(hostname, "localhost6.localdomain6") != 0) { hints.ai_flags |= AI_ADDRCONFIG; } #endif hints.ai_family = (af == PR_AF_INET) ? AF_INET : AF_UNSPEC; /* * it is important to select a socket type in the hints, otherwise we * will get back repetitive entries: one for each socket type. since * we do not expose ai_socktype through our API, it is okay to do this * here. the application may still choose to create a socket of some * other type. */ hints.ai_socktype = SOCK_STREAM; rv = GETADDRINFO(hostname, NULL, &hints, &res); #ifdef AI_ADDRCONFIG if (rv == EAI_BADFLAGS && (hints.ai_flags & AI_ADDRCONFIG)) { hints.ai_flags &= ~AI_ADDRCONFIG; rv = GETADDRINFO(hostname, NULL, &hints, &res); } #endif if (rv == 0) { return (PRAddrInfo *) res; } PR_SetError(PR_DIRECTORY_LOOKUP_ERROR, rv); } return NULL; #endif } PR_IMPLEMENT(void) PR_FreeAddrInfo(PRAddrInfo *ai) { #if defined(_PR_HAVE_GETADDRINFO) #if defined(_PR_INET6_PROBE) if (!_pr_ipv6_is_present()) { PR_Free((PRAddrInfoFB *) ai); } else #endif FREEADDRINFO((PRADDRINFO *) ai); #else PR_Free((PRAddrInfoFB *) ai); #endif } PR_IMPLEMENT(void *) PR_EnumerateAddrInfo(void *iterPtr, const PRAddrInfo *base, PRUint16 port, PRNetAddr *result) { #if defined(_PR_HAVE_GETADDRINFO) PRADDRINFO *ai; #if defined(_PR_INET6_PROBE) if (!_pr_ipv6_is_present()) { /* using PRAddrInfoFB */ PRIntn iter = (PRIntn)(PRPtrdiff) iterPtr; iter = PR_EnumerateHostEnt(iter, &((PRAddrInfoFB *) base)->hostent, port, result); if (iter < 0) { iter = 0; } return (void *)(PRPtrdiff) iter; } #endif if (iterPtr) { ai = ((PRADDRINFO *) iterPtr)->ai_next; } else { ai = (PRADDRINFO *) base; } while (ai && ai->ai_addrlen > sizeof(PRNetAddr)) { ai = ai->ai_next; } if (ai) { /* copy sockaddr to PRNetAddr */ memcpy(result, ai->ai_addr, ai->ai_addrlen); result->raw.family = ai->ai_addr->sa_family; #ifdef _PR_INET6 if (AF_INET6 == result->raw.family) { result->raw.family = PR_AF_INET6; } #endif if (ai->ai_addrlen < sizeof(PRNetAddr)) { memset(((char*)result)+ai->ai_addrlen, 0, sizeof(PRNetAddr) - ai->ai_addrlen); } if (result->raw.family == PR_AF_INET) { result->inet.port = htons(port); } else { result->ipv6.port = htons(port); } } return ai; #else /* using PRAddrInfoFB */ PRIntn iter = (PRIntn) iterPtr; iter = PR_EnumerateHostEnt(iter, &((PRAddrInfoFB *) base)->hostent, port, result); if (iter < 0) { iter = 0; } return (void *) iter; #endif } PR_IMPLEMENT(const char *) PR_GetCanonNameFromAddrInfo(const PRAddrInfo *ai) { #if defined(_PR_HAVE_GETADDRINFO) #if defined(_PR_INET6_PROBE) if (!_pr_ipv6_is_present()) { const PRAddrInfoFB *fb = (const PRAddrInfoFB *) ai; return fb->has_cname ? fb->hostent.h_name : NULL; } #endif return ((const PRADDRINFO *) ai)->ai_canonname; #else const PRAddrInfoFB *fb = (const PRAddrInfoFB *) ai; return fb->has_cname ? fb->hostent.h_name : NULL; #endif } #if defined(_PR_HAVE_GETADDRINFO) static PRStatus pr_StringToNetAddrGAI(const char *string, PRNetAddr *addr) { PRADDRINFO *res, hints; int rv; /* 0 for success, or the error code EAI_xxx */ PRNetAddr laddr; PRStatus status = PR_SUCCESS; memset(&hints, 0, sizeof(hints)); hints.ai_flags = AI_NUMERICHOST; hints.ai_family = AF_UNSPEC; hints.ai_socktype = SOCK_STREAM; rv = GETADDRINFO(string, NULL, &hints, &res); if (rv != 0) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, rv); return PR_FAILURE; } /* pick up the first addr */ memcpy(&laddr, res->ai_addr, res->ai_addrlen); if (AF_INET6 == res->ai_addr->sa_family) { addr->ipv6.family = PR_AF_INET6; addr->ipv6.ip = laddr.ipv6.ip; addr->ipv6.scope_id = laddr.ipv6.scope_id; } else if (AF_INET == res->ai_addr->sa_family) { addr->inet.family = PR_AF_INET; addr->inet.ip = laddr.inet.ip; } else { PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); status = PR_FAILURE; } FREEADDRINFO(res); return status; } #endif /* _PR_HAVE_GETADDRINFO */ static PRStatus pr_StringToNetAddrFB(const char *string, PRNetAddr *addr) { PRIntn rv; rv = pr_inet_aton(string, &addr->inet.ip); if (1 == rv) { addr->raw.family = AF_INET; return PR_SUCCESS; } PR_ASSERT(0 == rv); /* clean up after the failed call */ memset(&addr->inet.ip, 0, sizeof(addr->inet.ip)); rv = StringToV6Addr(string, &addr->ipv6.ip); if (1 == rv) { addr->raw.family = PR_AF_INET6; return PR_SUCCESS; } PR_ASSERT(0 == rv); PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); return PR_FAILURE; } PR_IMPLEMENT(PRStatus) PR_StringToNetAddr(const char *string, PRNetAddr *addr) { if (!_pr_initialized) { _PR_ImplicitInitialization(); } if (!addr || !string || !*string) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); return PR_FAILURE; } #if !defined(_PR_HAVE_GETADDRINFO) return pr_StringToNetAddrFB(string, addr); #else /* * getaddrinfo with AI_NUMERICHOST is much slower than pr_inet_aton on some * platforms, such as Mac OS X (bug 404399), Linux glibc 2.10 (bug 344809), * and most likely others. So we only use it to convert literal IP addresses * that contain IPv6 scope IDs, which pr_inet_aton cannot convert. */ if (!strchr(string, '%')) { return pr_StringToNetAddrFB(string, addr); } #if defined(_PR_INET6_PROBE) if (!_pr_ipv6_is_present()) { return pr_StringToNetAddrFB(string, addr); } #endif return pr_StringToNetAddrGAI(string, addr); #endif } #if defined(_PR_HAVE_GETADDRINFO) static PRStatus pr_NetAddrToStringGNI( const PRNetAddr *addr, char *string, PRUint32 size) { int addrlen; const PRNetAddr *addrp = addr; #if defined(_PR_HAVE_SOCKADDR_LEN) || defined(_PR_INET6) PRUint16 md_af = addr->raw.family; PRNetAddr addrcopy; #endif int rv; /* 0 for success, or the error code EAI_xxx */ #ifdef _PR_INET6 if (addr->raw.family == PR_AF_INET6) { md_af = AF_INET6; #ifndef _PR_HAVE_SOCKADDR_LEN addrcopy = *addr; addrcopy.raw.family = md_af; addrp = &addrcopy; #endif } #endif addrlen = PR_NETADDR_SIZE(addr); #ifdef _PR_HAVE_SOCKADDR_LEN addrcopy = *addr; ((struct sockaddr*)&addrcopy)->sa_len = addrlen; ((struct sockaddr*)&addrcopy)->sa_family = md_af; addrp = &addrcopy; #endif rv = GETNAMEINFO((const struct sockaddr *)addrp, addrlen, string, size, NULL, 0, NI_NUMERICHOST); if (rv != 0) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, rv); return PR_FAILURE; } return PR_SUCCESS; } #endif /* _PR_HAVE_GETADDRINFO */ #if !defined(_PR_HAVE_GETADDRINFO) || defined(_PR_INET6_PROBE) static PRStatus pr_NetAddrToStringFB( const PRNetAddr *addr, char *string, PRUint32 size) { if (PR_AF_INET6 == addr->raw.family) { #if defined(_PR_HAVE_INET_NTOP) if (NULL == inet_ntop(AF_INET6, &addr->ipv6.ip, string, size)) #else if (NULL == V6AddrToString(&addr->ipv6.ip, string, size)) #endif { /* the size of the result buffer is inadequate */ PR_SetError(PR_BUFFER_OVERFLOW_ERROR, 0); return PR_FAILURE; } } else { if (size < 16) { goto failed; } if (AF_INET != addr->raw.family) { goto failed; } else { unsigned char *byte = (unsigned char*)&addr->inet.ip; PR_snprintf(string, size, "%u.%u.%u.%u", byte[0], byte[1], byte[2], byte[3]); } } return PR_SUCCESS; failed: PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); return PR_FAILURE; } /* pr_NetAddrToStringFB */ #endif /* !_PR_HAVE_GETADDRINFO || _PR_INET6_PROBE */ PR_IMPLEMENT(PRStatus) PR_NetAddrToString( const PRNetAddr *addr, char *string, PRUint32 size) { if (!_pr_initialized) { _PR_ImplicitInitialization(); } #if !defined(_PR_HAVE_GETADDRINFO) return pr_NetAddrToStringFB(addr, string, size); #else #if defined(_PR_INET6_PROBE) if (!_pr_ipv6_is_present()) { return pr_NetAddrToStringFB(addr, string, size); } #endif return pr_NetAddrToStringGNI(addr, string, size); #endif } /* PR_NetAddrToString */