Current Path : /usr/src/contrib/ntp/ntpd/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //usr/src/contrib/ntp/ntpd/ntp_intres.c |
/* * ripped off from ../ntpres/ntpres.c by Greg Troxel 4/2/92 * routine callable from ntpd, rather than separate program * also, key info passed in via a global, so no key file needed. */ /* * ntpres - process configuration entries which require use of the resolver * * This is meant to be run by ntpd on the fly. It is not guaranteed * to work properly if run by hand. This is actually a quick hack to * stave off violence from people who hate using numbers in the * configuration file (at least I hope the rest of the daemon is * better than this). Also might provide some ideas about how one * might go about autoconfiguring an NTP distribution network. * */ #ifdef HAVE_CONFIG_H # include <config.h> #endif #include "ntp_machine.h" #include "ntpd.h" #include "ntp_io.h" #include "ntp_request.h" #include "ntp_stdlib.h" #include "ntp_syslog.h" #include <stdio.h> #include <ctype.h> #include <resolv.h> #include <signal.h> /**/ #include <netinet/in.h> #include <arpa/inet.h> /**/ #ifdef HAVE_SYS_PARAM_H # include <sys/param.h> /* MAXHOSTNAMELEN (often) */ #endif #include <isc/net.h> #include <isc/result.h> #define STREQ(a, b) (*(a) == *(b) && strcmp((a), (b)) == 0) /* * Each item we are to resolve and configure gets one of these * structures defined for it. */ struct conf_entry { struct conf_entry *ce_next; char *ce_name; /* name we are trying to resolve */ struct conf_peer ce_config; /* configuration info for peer */ struct sockaddr_storage peer_store; /* address info for both fams */ }; #define ce_peeraddr ce_config.peeraddr #define ce_peeraddr6 ce_config.peeraddr6 #define ce_hmode ce_config.hmode #define ce_version ce_config.version #define ce_minpoll ce_config.minpoll #define ce_maxpoll ce_config.maxpoll #define ce_flags ce_config.flags #define ce_ttl ce_config.ttl #define ce_keyid ce_config.keyid #define ce_keystr ce_config.keystr /* * confentries is a pointer to the list of configuration entries * we have left to do. */ static struct conf_entry *confentries = NULL; /* * We take an interrupt every thirty seconds, at which time we decrement * config_timer and resolve_timer. The former is set to 2, so we retry * unsucessful reconfigurations every minute. The latter is set to * an exponentially increasing value which starts at 2 and increases to * 32. When this expires we retry failed name resolutions. * * We sleep SLEEPTIME seconds before doing anything, to give the server * time to arrange itself. */ #define MINRESOLVE 2 #define MAXRESOLVE 32 #define CONFIG_TIME 2 #define ALARM_TIME 30 #define SLEEPTIME 2 static volatile int config_timer = 0; static volatile int resolve_timer = 0; static int resolve_value; /* next value of resolve timer */ /* * Big hack attack */ #define LOCALHOST 0x7f000001 /* 127.0.0.1, in hex, of course */ #define SKEWTIME 0x08000000 /* 0.03125 seconds as a l_fp fraction */ /* * Select time out. Set to 2 seconds. The server is on the local machine, * after all. */ #define TIMEOUT_SEC 2 #define TIMEOUT_USEC 0 /* * Input processing. The data on each line in the configuration file * is supposed to consist of entries in the following order */ #define TOK_HOSTNAME 0 #define TOK_PEERAF 1 #define TOK_HMODE 2 #define TOK_VERSION 3 #define TOK_MINPOLL 4 #define TOK_MAXPOLL 5 #define TOK_FLAGS 6 #define TOK_TTL 7 #define TOK_KEYID 8 #define TOK_KEYSTR 9 #define NUMTOK 10 #define MAXLINESIZE 512 /* * File descriptor for ntp request code. */ static SOCKET sockfd = INVALID_SOCKET; /* NT uses SOCKET */ /* stuff to be filled in by caller */ keyid_t req_keyid; /* request keyid */ char *req_file; /* name of the file with configuration info */ /* end stuff to be filled in */ static void checkparent P((void)); static void removeentry P((struct conf_entry *)); static void addentry P((char *, int, int, int, int, u_int, int, keyid_t, char *, u_char)); static int findhostaddr P((struct conf_entry *)); static void openntp P((void)); static int request P((struct conf_peer *)); static char * nexttoken P((char **)); static void readconf P((FILE *, char *)); static void doconfigure P((int)); struct ntp_res_t_pkt { /* Tagged packet: */ void *tag; /* For the caller */ u_int32 paddr; /* IP to look up, or 0 */ char name[MAXHOSTNAMELEN]; /* Name to look up (if 1st byte is not 0) */ }; struct ntp_res_c_pkt { /* Control packet: */ char name[MAXHOSTNAMELEN]; u_int32 paddr; int mode; int version; int minpoll; int maxpoll; u_int flags; int ttl; keyid_t keyid; u_char keystr[MAXFILENAME]; }; static void resolver_exit P((int)); /* * Call here instead of just exiting */ static void resolver_exit (int code) { #ifdef SYS_WINNT CloseHandle(ResolverEventHandle); ResolverEventHandle = NULL; ExitThread(code); /* Just to kill the thread not the process */ #else exit(code); /* kill the forked process */ #endif } /* * ntp_res_recv: Process an answer from the resolver */ void ntp_res_recv(void) { /* We have data ready on our descriptor. It may be an EOF, meaning the resolver process went away. Otherwise, it will be an "answer". */ } /* * ntp_intres needs; * * req_key(???), req_keyid, req_file valid * syslog still open */ void ntp_intres(void) { FILE *in; struct timeval tv; fd_set fdset; #ifdef SYS_WINNT DWORD rc; #else int rc; #endif #ifdef DEBUG if (debug > 1) { msyslog(LOG_INFO, "NTP_INTRES running"); } #endif /* check out auth stuff */ if (sys_authenticate) { if (!authistrusted(req_keyid)) { msyslog(LOG_ERR, "invalid request keyid %08x", req_keyid ); resolver_exit(1); } } /* * Read the configuration info * {this is bogus, since we are forked, but it is easier * to keep this code - gdt} */ if ((in = fopen(req_file, "r")) == NULL) { msyslog(LOG_ERR, "can't open configuration file %s: %m", req_file); resolver_exit(1); } readconf(in, req_file); (void) fclose(in); #ifdef DEBUG if (!debug ) #endif (void) unlink(req_file); /* * Set up the timers to do first shot immediately. */ resolve_timer = 0; resolve_value = MINRESOLVE; config_timer = CONFIG_TIME; for (;;) { checkparent(); if (resolve_timer == 0) { /* * Sleep a little to make sure the network is completely up */ sleep(SLEEPTIME); doconfigure(1); /* prepare retry, in case there's more work to do */ resolve_timer = resolve_value; #ifdef DEBUG if (debug > 2) msyslog(LOG_INFO, "resolve_timer: 0->%d", resolve_timer); #endif if (resolve_value < MAXRESOLVE) resolve_value <<= 1; config_timer = CONFIG_TIME; } else if (config_timer == 0) { /* MB: in which case would this be required ? */ doconfigure(0); /* MB: should we check now if we could exit, similar to the code above? */ config_timer = CONFIG_TIME; #ifdef DEBUG if (debug > 2) msyslog(LOG_INFO, "config_timer: 0->%d", config_timer); #endif } if (confentries == NULL) resolver_exit(0); /* done */ #ifdef SYS_WINNT rc = WaitForSingleObject(ResolverEventHandle, 1000 * ALARM_TIME); /* in milliseconds */ if ( rc == WAIT_OBJECT_0 ) { /* signaled by the main thread */ resolve_timer = 0; /* retry resolving immediately */ continue; } if ( rc != WAIT_TIMEOUT ) /* not timeout: error */ resolver_exit(1); #else /* not SYS_WINNT */ tv.tv_sec = ALARM_TIME; tv.tv_usec = 0; FD_ZERO(&fdset); FD_SET(resolver_pipe_fd[0], &fdset); rc = select(resolver_pipe_fd[0] + 1, &fdset, (fd_set *)0, (fd_set *)0, &tv); if (rc > 0) { /* parent process has written to the pipe */ read(resolver_pipe_fd[0], (char *)&rc, sizeof(rc)); /* make pipe empty */ resolve_timer = 0; /* retry resolving immediately */ continue; } if ( rc < 0 ) /* select() returned error */ resolver_exit(1); #endif /* normal timeout, keep on waiting */ if (config_timer > 0) config_timer--; if (resolve_timer > 0) resolve_timer--; } } /* * checkparent - see if our parent process is still running * * No need to worry in the Windows NT environment whether the * main thread is still running, because if it goes * down it takes the whole process down with it (in * which case we won't be running this thread either) * Turn function into NOP; */ static void checkparent(void) { #if !defined (SYS_WINNT) && !defined (SYS_VXWORKS) /* * If our parent (the server) has died we will have been * inherited by init. If so, exit. */ if (getppid() == 1) { msyslog(LOG_INFO, "parent died before we finished, exiting"); resolver_exit(0); } #endif /* SYS_WINNT && SYS_VXWORKS*/ } /* * removeentry - we are done with an entry, remove it from the list */ static void removeentry( struct conf_entry *entry ) { register struct conf_entry *ce; ce = confentries; if (ce == entry) { confentries = ce->ce_next; return; } while (ce != NULL) { if (ce->ce_next == entry) { ce->ce_next = entry->ce_next; return; } ce = ce->ce_next; } } /* * addentry - add an entry to the configuration list */ static void addentry( char *name, int mode, int version, int minpoll, int maxpoll, u_int flags, int ttl, keyid_t keyid, char *keystr, u_char peeraf ) { register char *cp; register struct conf_entry *ce; unsigned int len; #ifdef DEBUG if (debug > 1) msyslog(LOG_INFO, "intres: <%s> %u %d %d %d %d %x %d %x %s\n", name, peeraf, mode, version, minpoll, maxpoll, flags, ttl, keyid, keystr); #endif len = strlen(name) + 1; cp = (char *)emalloc(len); memmove(cp, name, len); ce = (struct conf_entry *)emalloc(sizeof(struct conf_entry)); ce->ce_name = cp; ce->ce_peeraddr = 0; #ifdef ISC_PLATFORM_HAVEIPV6 ce->ce_peeraddr6 = in6addr_any; #endif ANYSOCK(&ce->peer_store); ce->peer_store.ss_family = peeraf; /* Save AF for getaddrinfo hints. */ ce->ce_hmode = (u_char)mode; ce->ce_version = (u_char)version; ce->ce_minpoll = (u_char)minpoll; ce->ce_maxpoll = (u_char)maxpoll; ce->ce_flags = (u_char)flags; ce->ce_ttl = (u_char)ttl; ce->ce_keyid = keyid; strncpy((char *)ce->ce_keystr, keystr, MAXFILENAME); ce->ce_next = NULL; if (confentries == NULL) { confentries = ce; } else { register struct conf_entry *cep; for (cep = confentries; cep->ce_next != NULL; cep = cep->ce_next) /* nothing */; cep->ce_next = ce; } } /* * findhostaddr - resolve a host name into an address (Or vice-versa) * * Given one of {ce_peeraddr,ce_name}, find the other one. * It returns 1 for "success" and 0 for an uncorrectable failure. * Note that "success" includes try again errors. You can tell that you * got a "try again" since {ce_peeraddr,ce_name} will still be zero. */ static int findhostaddr( struct conf_entry *entry ) { static int eai_again_seen = 0; struct addrinfo *addr; struct addrinfo hints; int again; int error; checkparent(); /* make sure our guy is still running */ if (entry->ce_name != NULL && !SOCKNUL(&entry->peer_store)) { /* HMS: Squawk? */ msyslog(LOG_ERR, "findhostaddr: both ce_name and ce_peeraddr are defined..."); return 1; } if (entry->ce_name == NULL && SOCKNUL(&entry->peer_store)) { msyslog(LOG_ERR, "findhostaddr: both ce_name and ce_peeraddr are undefined!"); return 0; } if (entry->ce_name) { DPRINTF(2, ("findhostaddr: Resolving <%s>\n", entry->ce_name)); memset(&hints, 0, sizeof(hints)); hints.ai_family = entry->peer_store.ss_family; hints.ai_socktype = SOCK_DGRAM; /* * If the IPv6 stack is not available look only for IPv4 addresses */ if (isc_net_probeipv6() != ISC_R_SUCCESS) hints.ai_family = AF_INET; error = getaddrinfo(entry->ce_name, NULL, &hints, &addr); if (error == 0) { entry->peer_store = *((struct sockaddr_storage*)(addr->ai_addr)); if (entry->peer_store.ss_family == AF_INET) { entry->ce_peeraddr = GET_INADDR(entry->peer_store); entry->ce_config.v6_flag = 0; } else { entry->ce_peeraddr6 = GET_INADDR6(entry->peer_store); entry->ce_config.v6_flag = 1; } } } else { DPRINTF(2, ("findhostaddr: Resolving <%s>\n", stoa(&entry->peer_store))); entry->ce_name = emalloc(MAXHOSTNAMELEN); error = getnameinfo((const struct sockaddr *)&entry->peer_store, SOCKLEN(&entry->peer_store), (char *)&entry->ce_name, MAXHOSTNAMELEN, NULL, 0, 0); } if (0 == error) { /* again is our return value, for success it is 1 */ again = 1; DPRINTF(2, ("findhostaddr: %s resolved.\n", (entry->ce_name) ? "name" : "address")); } else { /* * If the resolver failed, see if the failure is * temporary. If so, return success. */ again = 0; switch (error) { case EAI_FAIL: again = 1; break; case EAI_AGAIN: again = 1; eai_again_seen = 1; break; case EAI_NONAME: #if defined(EAI_NODATA) && (EAI_NODATA != EAI_NONAME) case EAI_NODATA: #endif msyslog(LOG_ERR, "host name not found%s%s: %s", (EAI_NONAME == error) ? "" : " EAI_NODATA", (eai_again_seen) ? " (permanent)" : "", entry->ce_name); again = !eai_again_seen; break; #ifdef EAI_SYSTEM case EAI_SYSTEM: /* * EAI_SYSTEM means the real error is in errno. We should be more * discriminating about which errno values require retrying, but * this matches existing behavior. */ again = 1; DPRINTF(1, ("intres: EAI_SYSTEM errno %d (%s) means try again, right?\n", errno, strerror(errno))); break; #endif } /* do this here to avoid perturbing errno earlier */ DPRINTF(2, ("intres: got error status of: %d\n", error)); } return again; } /* * openntp - open a socket to the ntp server */ static void openntp(void) { const char *localhost = "127.0.0.1"; /* Use IPv4 loopback */ struct addrinfo hints; struct addrinfo *addr; u_long on; int err; if (sockfd != INVALID_SOCKET) return; memset(&hints, 0, sizeof(hints)); /* * For now only bother with IPv4 */ hints.ai_family = AF_INET; hints.ai_socktype = SOCK_DGRAM; err = getaddrinfo(localhost, "ntp", &hints, &addr); if (err) { #ifdef EAI_SYSTEM if (EAI_SYSTEM == err) msyslog(LOG_ERR, "getaddrinfo(%s) failed: %m", localhost); else #endif msyslog(LOG_ERR, "getaddrinfo(%s) failed: %s", localhost, gai_strerror(err)); resolver_exit(1); } sockfd = socket(addr->ai_family, addr->ai_socktype, 0); if (INVALID_SOCKET == sockfd) { msyslog(LOG_ERR, "socket() failed: %m"); resolver_exit(1); } #ifndef SYS_WINNT /* * On Windows only the count of sockets must be less than * FD_SETSIZE. On Unix each descriptor's value must be less * than FD_SETSIZE, as fd_set is a bit array. */ if (sockfd >= FD_SETSIZE) { msyslog(LOG_ERR, "socket fd %d too large, FD_SETSIZE %d", (int)sockfd, FD_SETSIZE); resolver_exit(1); } /* * Make the socket non-blocking. We'll wait with select() * Unix: fcntl(O_NONBLOCK) or fcntl(FNDELAY) */ # ifdef O_NONBLOCK if (fcntl(sockfd, F_SETFL, O_NONBLOCK) == -1) { msyslog(LOG_ERR, "fcntl(O_NONBLOCK) failed: %m"); resolver_exit(1); } # else # ifdef FNDELAY if (fcntl(sockfd, F_SETFL, FNDELAY) == -1) { msyslog(LOG_ERR, "fcntl(FNDELAY) failed: %m"); resolver_exit(1); } # else # include "Bletch: NEED NON BLOCKING IO" # endif /* FNDDELAY */ # endif /* O_NONBLOCK */ (void)on; /* quiet unused warning */ #else /* !SYS_WINNT above */ /* * Make the socket non-blocking. We'll wait with select() * Windows: ioctlsocket(FIONBIO) */ on = 1; err = ioctlsocket(sockfd, FIONBIO, &on); if (SOCKET_ERROR == err) { msyslog(LOG_ERR, "ioctlsocket(FIONBIO) fails: %m"); resolver_exit(1); } #endif /* SYS_WINNT */ err = connect(sockfd, addr->ai_addr, addr->ai_addrlen); if (SOCKET_ERROR == err) { msyslog(LOG_ERR, "openntp: connect() failed: %m"); resolver_exit(1); } freeaddrinfo(addr); } /* * request - send a configuration request to the server, wait for a response */ static int request( struct conf_peer *conf ) { fd_set fdset; struct timeval tvout; struct req_pkt reqpkt; l_fp ts; int n; #ifdef SYS_WINNT HANDLE hReadWriteEvent = NULL; BOOL ret; DWORD NumberOfBytesWritten, NumberOfBytesRead, dwWait; OVERLAPPED overlap; #endif /* SYS_WINNT */ checkparent(); /* make sure our guy is still running */ if (sockfd == INVALID_SOCKET) openntp(); #ifdef SYS_WINNT hReadWriteEvent = CreateEvent(NULL, FALSE, FALSE, NULL); #endif /* SYS_WINNT */ /* * Try to clear out any previously received traffic so it * doesn't fool us. Note the socket is nonblocking. */ tvout.tv_sec = 0; tvout.tv_usec = 0; FD_ZERO(&fdset); FD_SET(sockfd, &fdset); while (select(sockfd + 1, &fdset, (fd_set *)0, (fd_set *)0, &tvout) > 0) { recv(sockfd, (char *)&reqpkt, REQ_LEN_MAC, 0); FD_ZERO(&fdset); FD_SET(sockfd, &fdset); } /* * Make up a request packet with the configuration info */ memset((char *)&reqpkt, 0, sizeof(reqpkt)); reqpkt.rm_vn_mode = RM_VN_MODE(0, 0, 0); reqpkt.auth_seq = AUTH_SEQ(1, 0); /* authenticated, no seq */ reqpkt.implementation = IMPL_XNTPD; /* local implementation */ reqpkt.request = REQ_CONFIG; /* configure a new peer */ reqpkt.err_nitems = ERR_NITEMS(0, 1); /* one item */ reqpkt.mbz_itemsize = MBZ_ITEMSIZE(sizeof(struct conf_peer)); /* Make sure mbz_itemsize <= sizeof reqpkt.data */ if (sizeof(struct conf_peer) > sizeof (reqpkt.data)) { msyslog(LOG_ERR, "Bletch: conf_peer is too big for reqpkt.data!"); resolver_exit(1); } memmove(reqpkt.data, (char *)conf, sizeof(struct conf_peer)); reqpkt.keyid = htonl(req_keyid); get_systime(&ts); L_ADDUF(&ts, SKEWTIME); HTONL_FP(&ts, &reqpkt.tstamp); n = 0; if (sys_authenticate) n = authencrypt(req_keyid, (u_int32 *)&reqpkt, REQ_LEN_NOMAC); /* * Done. Send it. */ #ifndef SYS_WINNT n = send(sockfd, (char *)&reqpkt, (unsigned)(REQ_LEN_NOMAC + n), 0); if (n < 0) { msyslog(LOG_ERR, "send to NTP server failed: %m"); return 0; /* maybe should exit */ } #else /* In the NT world, documentation seems to indicate that there * exist _write and _read routines that can be used to do blocking * I/O on sockets. Problem is these routines require a socket * handle obtained through the _open_osf_handle C run-time API * of which there is no explanation in the documentation. We need * nonblocking write's and read's anyway for our purpose here. * We're therefore forced to deviate a little bit from the Unix * model here and use the ReadFile and WriteFile Win32 I/O API's * on the socket */ overlap.Offset = overlap.OffsetHigh = (DWORD)0; overlap.hEvent = hReadWriteEvent; ret = WriteFile((HANDLE)sockfd, (char *)&reqpkt, REQ_LEN_NOMAC + n, NULL, (LPOVERLAPPED)&overlap); if ((ret == FALSE) && (GetLastError() != ERROR_IO_PENDING)) { msyslog(LOG_ERR, "send to NTP server failed: %m"); return 0; } dwWait = WaitForSingleObject(hReadWriteEvent, (DWORD) TIMEOUT_SEC * 1000); if ((dwWait == WAIT_FAILED) || (dwWait == WAIT_TIMEOUT)) { if (dwWait == WAIT_FAILED) msyslog(LOG_ERR, "WaitForSingleObject failed: %m"); return 0; } if (!GetOverlappedResult((HANDLE)sockfd, (LPOVERLAPPED)&overlap, (LPDWORD)&NumberOfBytesWritten, FALSE)) { msyslog(LOG_ERR, "GetOverlappedResult for WriteFile fails: %m"); return 0; } #endif /* SYS_WINNT */ /* * Wait for a response. A weakness of the mode 7 protocol used * is that there is no way to associate a response with a * particular request, i.e. the response to this configuration * request is indistinguishable from that to any other. I should * fix this some day. In any event, the time out is fairly * pessimistic to make sure that if an answer is coming back * at all, we get it. */ for (;;) { FD_ZERO(&fdset); FD_SET(sockfd, &fdset); tvout.tv_sec = TIMEOUT_SEC; tvout.tv_usec = TIMEOUT_USEC; n = select(sockfd + 1, &fdset, (fd_set *)0, (fd_set *)0, &tvout); if (n < 0) { if (errno != EINTR) msyslog(LOG_ERR, "select() fails: %m"); return 0; } else if (n == 0) { #ifdef DEBUG if (debug) msyslog(LOG_INFO, "select() returned 0."); #endif return 0; } #ifndef SYS_WINNT n = recv(sockfd, (char *)&reqpkt, REQ_LEN_MAC, 0); if (n <= 0) { if (n < 0) { msyslog(LOG_ERR, "recv() fails: %m"); return 0; } continue; } #else /* Overlapped I/O used on non-blocking sockets on Windows NT */ ret = ReadFile((HANDLE)sockfd, (char *)&reqpkt, (DWORD)REQ_LEN_MAC, NULL, (LPOVERLAPPED)&overlap); if ((ret == FALSE) && (GetLastError() != ERROR_IO_PENDING)) { msyslog(LOG_ERR, "ReadFile() fails: %m"); return 0; } dwWait = WaitForSingleObject(hReadWriteEvent, (DWORD) TIMEOUT_SEC * 1000); if ((dwWait == WAIT_FAILED) || (dwWait == WAIT_TIMEOUT)) { if (dwWait == WAIT_FAILED) { msyslog(LOG_ERR, "WaitForSingleObject for ReadFile fails: %m"); return 0; } continue; } if (!GetOverlappedResult((HANDLE)sockfd, (LPOVERLAPPED)&overlap, (LPDWORD)&NumberOfBytesRead, FALSE)) { msyslog(LOG_ERR, "GetOverlappedResult fails: %m"); return 0; } n = NumberOfBytesRead; #endif /* SYS_WINNT */ /* * Got one. Check through to make sure it is what * we expect. */ if (n < RESP_HEADER_SIZE) { msyslog(LOG_ERR, "received runt response (%d octets)", n); continue; } if (!ISRESPONSE(reqpkt.rm_vn_mode)) { #ifdef DEBUG if (debug > 1) msyslog(LOG_INFO, "received non-response packet"); #endif continue; } if (ISMORE(reqpkt.rm_vn_mode)) { #ifdef DEBUG if (debug > 1) msyslog(LOG_INFO, "received fragmented packet"); #endif continue; } if ( ( (INFO_VERSION(reqpkt.rm_vn_mode) < 2) || (INFO_VERSION(reqpkt.rm_vn_mode) > NTP_VERSION)) || INFO_MODE(reqpkt.rm_vn_mode) != MODE_PRIVATE) { #ifdef DEBUG if (debug > 1) msyslog(LOG_INFO, "version (%d/%d) or mode (%d/%d) incorrect", INFO_VERSION(reqpkt.rm_vn_mode), NTP_VERSION, INFO_MODE(reqpkt.rm_vn_mode), MODE_PRIVATE); #endif continue; } if (INFO_SEQ(reqpkt.auth_seq) != 0) { #ifdef DEBUG if (debug > 1) msyslog(LOG_INFO, "nonzero sequence number (%d)", INFO_SEQ(reqpkt.auth_seq)); #endif continue; } if (reqpkt.implementation != IMPL_XNTPD || reqpkt.request != REQ_CONFIG) { #ifdef DEBUG if (debug > 1) msyslog(LOG_INFO, "implementation (%d) or request (%d) incorrect", reqpkt.implementation, reqpkt.request); #endif continue; } if (INFO_NITEMS(reqpkt.err_nitems) != 0 || INFO_MBZ(reqpkt.mbz_itemsize) != 0 || INFO_ITEMSIZE(reqpkt.mbz_itemsize) != 0) { #ifdef DEBUG if (debug > 1) msyslog(LOG_INFO, "nitems (%d) mbz (%d) or itemsize (%d) nonzero", INFO_NITEMS(reqpkt.err_nitems), INFO_MBZ(reqpkt.mbz_itemsize), INFO_ITEMSIZE(reqpkt.mbz_itemsize)); #endif continue; } n = INFO_ERR(reqpkt.err_nitems); switch (n) { case INFO_OKAY: /* success */ return 1; case INFO_ERR_IMPL: msyslog(LOG_ERR, "ntpd reports implementation mismatch!"); return 0; case INFO_ERR_REQ: msyslog(LOG_ERR, "ntpd says configuration request is unknown!"); return 0; case INFO_ERR_FMT: msyslog(LOG_ERR, "ntpd indicates a format error occurred!"); return 0; case INFO_ERR_NODATA: msyslog(LOG_ERR, "ntpd indicates no data available!"); return 0; case INFO_ERR_AUTH: msyslog(LOG_ERR, "ntpd returns a permission denied error!"); return 0; default: msyslog(LOG_ERR, "ntpd returns unknown error code %d!", n); return 0; } } } /* * nexttoken - return the next token from a line */ static char * nexttoken( char **lptr ) { register char *cp; register char *tstart; cp = *lptr; /* * Skip leading white space */ while (*cp == ' ' || *cp == '\t') cp++; /* * If this is the end of the line, return nothing. */ if (*cp == '\n' || *cp == '\0') { *lptr = cp; return NULL; } /* * Must be the start of a token. Record the pointer and look * for the end. */ tstart = cp++; while (*cp != ' ' && *cp != '\t' && *cp != '\n' && *cp != '\0') cp++; /* * Terminate the token with a \0. If this isn't the end of the * line, space to the next character. */ if (*cp == '\n' || *cp == '\0') *cp = '\0'; else *cp++ = '\0'; *lptr = cp; return tstart; } /* * readconf - read the configuration information out of the file we * were passed. Note that since the file is supposed to be * machine generated, we bail out at the first sign of trouble. */ static void readconf( FILE *fp, char *name ) { register int i; char *token[NUMTOK]; u_long intval[NUMTOK]; u_int flags; char buf[MAXLINESIZE]; char *bp; while (fgets(buf, MAXLINESIZE, fp) != NULL) { bp = buf; for (i = 0; i < NUMTOK; i++) { if ((token[i] = nexttoken(&bp)) == NULL) { msyslog(LOG_ERR, "tokenizing error in file `%s', quitting", name); resolver_exit(1); } } for (i = 1; i < NUMTOK - 1; i++) { if (!atouint(token[i], &intval[i])) { msyslog(LOG_ERR, "format error for integer token `%s', file `%s', quitting", token[i], name); resolver_exit(1); } } if (intval[TOK_PEERAF] != AF_UNSPEC && intval[TOK_PEERAF] != AF_INET && intval[TOK_PEERAF] != AF_INET6) { msyslog(LOG_ERR, "invalid peer address family (%u) in " "file %s", intval[TOK_PEERAF], name); exit(1); } if (intval[TOK_HMODE] != MODE_ACTIVE && intval[TOK_HMODE] != MODE_CLIENT && intval[TOK_HMODE] != MODE_BROADCAST) { msyslog(LOG_ERR, "invalid mode (%ld) in file %s", intval[TOK_HMODE], name); resolver_exit(1); } if (intval[TOK_VERSION] > NTP_VERSION || intval[TOK_VERSION] < NTP_OLDVERSION) { msyslog(LOG_ERR, "invalid version (%ld) in file %s", intval[TOK_VERSION], name); resolver_exit(1); } if (intval[TOK_MINPOLL] < NTP_MINPOLL || intval[TOK_MINPOLL] > NTP_MAXPOLL) { msyslog(LOG_ERR, "invalid MINPOLL value (%ld) in file %s", intval[TOK_MINPOLL], name); resolver_exit(1); } if (intval[TOK_MAXPOLL] < NTP_MINPOLL || intval[TOK_MAXPOLL] > NTP_MAXPOLL) { msyslog(LOG_ERR, "invalid MAXPOLL value (%ld) in file %s", intval[TOK_MAXPOLL], name); resolver_exit(1); } if ((intval[TOK_FLAGS] & ~(FLAG_AUTHENABLE | FLAG_PREFER | FLAG_NOSELECT | FLAG_BURST | FLAG_IBURST | FLAG_SKEY)) != 0) { msyslog(LOG_ERR, "invalid flags (%ld) in file %s", intval[TOK_FLAGS], name); resolver_exit(1); } flags = 0; if (intval[TOK_FLAGS] & FLAG_AUTHENABLE) flags |= CONF_FLAG_AUTHENABLE; if (intval[TOK_FLAGS] & FLAG_PREFER) flags |= CONF_FLAG_PREFER; if (intval[TOK_FLAGS] & FLAG_NOSELECT) flags |= CONF_FLAG_NOSELECT; if (intval[TOK_FLAGS] & FLAG_BURST) flags |= CONF_FLAG_BURST; if (intval[TOK_FLAGS] & FLAG_IBURST) flags |= CONF_FLAG_IBURST; if (intval[TOK_FLAGS] & FLAG_SKEY) flags |= CONF_FLAG_SKEY; /* * This is as good as we can check it. Add it in. */ addentry(token[TOK_HOSTNAME], (int)intval[TOK_HMODE], (int)intval[TOK_VERSION], (int)intval[TOK_MINPOLL], (int)intval[TOK_MAXPOLL], flags, (int)intval[TOK_TTL], intval[TOK_KEYID], token[TOK_KEYSTR], (u_char)intval[TOK_PEERAF]); } } /* * doconfigure - attempt to resolve names and configure the server */ static void doconfigure( int dores ) { register struct conf_entry *ce; register struct conf_entry *ceremove; #ifdef DEBUG if (debug > 1) msyslog(LOG_INFO, "Running doconfigure %s DNS", dores ? "with" : "without" ); #endif if (dores) /* Reload /etc/resolv.conf - bug 1226 */ res_init(); ce = confentries; while (ce != NULL) { #ifdef DEBUG if (debug > 1) msyslog(LOG_INFO, "doconfigure: <%s> has peeraddr %s", ce->ce_name, stoa(&ce->peer_store)); #endif if (dores && SOCKNUL(&(ce->peer_store))) { if (!findhostaddr(ce)) { #ifndef IGNORE_DNS_ERRORS msyslog(LOG_ERR, "couldn't resolve `%s', giving up on it", ce->ce_name); ceremove = ce; ce = ceremove->ce_next; removeentry(ceremove); continue; #endif } } if (!SOCKNUL(&ce->peer_store)) { if (request(&ce->ce_config)) { ceremove = ce; ce = ceremove->ce_next; removeentry(ceremove); continue; } #ifdef DEBUG if (debug > 1) { msyslog(LOG_INFO, "doconfigure: request() FAILED, maybe next time."); } #endif } ce = ce->ce_next; } }