ntpq.c revision 1.1.1.10
1 1.1.1.10 christos /* $NetBSD: ntpq.c,v 1.1.1.10 2016/01/08 21:21:27 christos Exp $ */ 2 1.1.1.10 christos 3 1.1 kardel /* 4 1.1 kardel * ntpq - query an NTP server using mode 6 commands 5 1.1 kardel */ 6 1.1.1.3 christos #include <config.h> 7 1.1 kardel #include <stdio.h> 8 1.1 kardel #include <ctype.h> 9 1.1 kardel #include <signal.h> 10 1.1 kardel #include <setjmp.h> 11 1.1 kardel #include <sys/types.h> 12 1.1 kardel #include <sys/time.h> 13 1.1.1.3 christos #ifdef HAVE_UNISTD_H 14 1.1.1.3 christos # include <unistd.h> 15 1.1.1.3 christos #endif 16 1.1.1.3 christos #ifdef HAVE_FCNTL_H 17 1.1.1.3 christos # include <fcntl.h> 18 1.1.1.3 christos #endif 19 1.1.1.3 christos #ifdef SYS_WINNT 20 1.1.1.3 christos # include <mswsock.h> 21 1.1.1.3 christos #endif 22 1.1.1.3 christos #include <isc/net.h> 23 1.1.1.3 christos #include <isc/result.h> 24 1.1 kardel 25 1.1 kardel #include "ntpq.h" 26 1.1.1.6 christos #include "ntp_assert.h" 27 1.1.1.3 christos #include "ntp_stdlib.h" 28 1.1 kardel #include "ntp_unixtime.h" 29 1.1 kardel #include "ntp_calendar.h" 30 1.1 kardel #include "ntp_select.h" 31 1.1 kardel #include "ntp_assert.h" 32 1.1.1.3 christos #include "lib_strbuf.h" 33 1.1 kardel #include "ntp_lineedit.h" 34 1.1 kardel #include "ntp_debug.h" 35 1.1.1.3 christos #ifdef OPENSSL 36 1.1.1.3 christos #include "openssl/evp.h" 37 1.1.1.3 christos #include "openssl/objects.h" 38 1.1.1.6 christos #include "openssl/err.h" 39 1.1.1.3 christos #endif 40 1.1 kardel #include <ssl_applink.c> 41 1.1 kardel 42 1.1.1.2 kardel #include "ntp_libopts.h" 43 1.1 kardel #include "ntpq-opts.h" 44 1.1.1.9 christos #include "safecast.h" 45 1.1 kardel 46 1.1.1.3 christos #ifdef SYS_VXWORKS /* vxWorks needs mode flag -casey*/ 47 1.1 kardel # define open(name, flags) open(name, flags, 0777) 48 1.1 kardel # define SERVER_PORT_NUM 123 49 1.1 kardel #endif 50 1.1 kardel 51 1.1 kardel /* we use COMMAND as an autogen keyword */ 52 1.1 kardel #ifdef COMMAND 53 1.1 kardel # undef COMMAND 54 1.1 kardel #endif 55 1.1 kardel 56 1.1 kardel /* 57 1.1 kardel * Because we potentially understand a lot of commands we will run 58 1.1 kardel * interactive if connected to a terminal. 59 1.1 kardel */ 60 1.1 kardel int interactive = 0; /* set to 1 when we should prompt */ 61 1.1 kardel const char *prompt = "ntpq> "; /* prompt to ask him about */ 62 1.1 kardel 63 1.1 kardel /* 64 1.1 kardel * use old readvars behavior? --old-rv processing in ntpq resets 65 1.1 kardel * this value based on the presence or absence of --old-rv. It is 66 1.1 kardel * initialized to 1 here to maintain backward compatibility with 67 1.1 kardel * libntpq clients such as ntpsnmpd, which are free to reset it as 68 1.1 kardel * desired. 69 1.1 kardel */ 70 1.1 kardel int old_rv = 1; 71 1.1 kardel 72 1.1 kardel 73 1.1 kardel /* 74 1.1 kardel * for get_systime() 75 1.1 kardel */ 76 1.1 kardel s_char sys_precision; /* local clock precision (log2 s) */ 77 1.1 kardel 78 1.1 kardel /* 79 1.1 kardel * Keyid used for authenticated requests. Obtained on the fly. 80 1.1 kardel */ 81 1.1 kardel u_long info_auth_keyid = 0; 82 1.1 kardel 83 1.1 kardel static int info_auth_keytype = NID_md5; /* MD5 */ 84 1.1 kardel static size_t info_auth_hashlen = 16; /* MD5 */ 85 1.1 kardel u_long current_time; /* needed by authkeys; not used */ 86 1.1 kardel 87 1.1 kardel /* 88 1.1 kardel * Flag which indicates we should always send authenticated requests 89 1.1 kardel */ 90 1.1 kardel int always_auth = 0; 91 1.1 kardel 92 1.1 kardel /* 93 1.1 kardel * Flag which indicates raw mode output. 94 1.1 kardel */ 95 1.1 kardel int rawmode = 0; 96 1.1 kardel 97 1.1 kardel /* 98 1.1 kardel * Packet version number we use 99 1.1 kardel */ 100 1.1 kardel u_char pktversion = NTP_OLDVERSION + 1; 101 1.1 kardel 102 1.1 kardel /* 103 1.1 kardel * Don't jump if no set jmp. 104 1.1 kardel */ 105 1.1 kardel volatile int jump = 0; 106 1.1 kardel 107 1.1 kardel /* 108 1.1 kardel * Format values 109 1.1 kardel */ 110 1.1 kardel #define PADDING 0 111 1.1.1.3 christos #define HA 1 /* host address */ 112 1.1.1.3 christos #define NA 2 /* network address */ 113 1.1.1.3 christos #define LP 3 /* leap (print in binary) */ 114 1.1.1.3 christos #define RF 4 /* refid (sometimes string, sometimes not) */ 115 1.1.1.3 christos #define AR 5 /* array of times */ 116 1.1.1.3 christos #define FX 6 /* test flags */ 117 1.1.1.3 christos #define TS 7 /* l_fp timestamp in hex */ 118 1.1.1.3 christos #define OC 8 /* integer, print in octal */ 119 1.1 kardel #define EOV 255 /* end of table */ 120 1.1 kardel 121 1.1 kardel /* 122 1.1.1.3 christos * For the most part ntpq simply displays what ntpd provides in the 123 1.1.1.3 christos * mostly plain-text mode 6 responses. A few variable names are by 124 1.1.1.3 christos * default "cooked" to provide more human-friendly output. 125 1.1.1.3 christos */ 126 1.1.1.3 christos const var_format cookedvars[] = { 127 1.1.1.3 christos { "leap", LP }, 128 1.1.1.3 christos { "reach", OC }, 129 1.1.1.3 christos { "refid", RF }, 130 1.1.1.3 christos { "reftime", TS }, 131 1.1.1.3 christos { "clock", TS }, 132 1.1.1.3 christos { "org", TS }, 133 1.1.1.3 christos { "rec", TS }, 134 1.1.1.3 christos { "xmt", TS }, 135 1.1.1.3 christos { "flash", FX }, 136 1.1.1.3 christos { "srcadr", HA }, 137 1.1.1.3 christos { "peeradr", HA }, /* compat with others */ 138 1.1.1.3 christos { "dstadr", NA }, 139 1.1.1.3 christos { "filtdelay", AR }, 140 1.1.1.3 christos { "filtoffset", AR }, 141 1.1.1.3 christos { "filtdisp", AR }, 142 1.1.1.3 christos { "filterror", AR }, /* compat with others */ 143 1.1 kardel }; 144 1.1 kardel 145 1.1 kardel 146 1.1 kardel 147 1.1 kardel /* 148 1.1 kardel * flasher bits 149 1.1 kardel */ 150 1.1 kardel static const char *tstflagnames[] = { 151 1.1 kardel "pkt_dup", /* TEST1 */ 152 1.1 kardel "pkt_bogus", /* TEST2 */ 153 1.1 kardel "pkt_unsync", /* TEST3 */ 154 1.1 kardel "pkt_denied", /* TEST4 */ 155 1.1 kardel "pkt_auth", /* TEST5 */ 156 1.1 kardel "pkt_stratum", /* TEST6 */ 157 1.1 kardel "pkt_header", /* TEST7 */ 158 1.1 kardel "pkt_autokey", /* TEST8 */ 159 1.1 kardel "pkt_crypto", /* TEST9 */ 160 1.1 kardel "peer_stratum", /* TEST10 */ 161 1.1 kardel "peer_dist", /* TEST11 */ 162 1.1 kardel "peer_loop", /* TEST12 */ 163 1.1 kardel "peer_unreach" /* TEST13 */ 164 1.1 kardel }; 165 1.1 kardel 166 1.1 kardel 167 1.1 kardel int ntpqmain (int, char **); 168 1.1 kardel /* 169 1.1 kardel * Built in command handler declarations 170 1.1 kardel */ 171 1.1.1.3 christos static int openhost (const char *, int); 172 1.1.1.3 christos static void dump_hex_printable(const void *, size_t); 173 1.1 kardel static int sendpkt (void *, size_t); 174 1.1.1.9 christos static int getresponse (int, int, u_short *, size_t *, const char **, int); 175 1.1.1.9 christos static int sendrequest (int, associd_t, int, size_t, const char *); 176 1.1 kardel static char * tstflags (u_long); 177 1.1 kardel #ifndef BUILD_AS_LIB 178 1.1 kardel static void getcmds (void); 179 1.1 kardel #ifndef SYS_WINNT 180 1.1.1.9 christos static int abortcmd (void); 181 1.1 kardel #endif /* SYS_WINNT */ 182 1.1 kardel static void docmd (const char *); 183 1.1 kardel static void tokenize (const char *, char **, int *); 184 1.1.1.3 christos static int getarg (const char *, int, arg_v *); 185 1.1 kardel #endif /* BUILD_AS_LIB */ 186 1.1.1.3 christos static int findcmd (const char *, struct xcmd *, 187 1.1.1.3 christos struct xcmd *, struct xcmd **); 188 1.1 kardel static int rtdatetolfp (char *, l_fp *); 189 1.1 kardel static int decodearr (char *, int *, l_fp *); 190 1.1 kardel static void help (struct parse *, FILE *); 191 1.1 kardel static int helpsort (const void *, const void *); 192 1.1 kardel static void printusage (struct xcmd *, FILE *); 193 1.1 kardel static void timeout (struct parse *, FILE *); 194 1.1 kardel static void auth_delay (struct parse *, FILE *); 195 1.1 kardel static void host (struct parse *, FILE *); 196 1.1 kardel static void ntp_poll (struct parse *, FILE *); 197 1.1 kardel static void keyid (struct parse *, FILE *); 198 1.1 kardel static void keytype (struct parse *, FILE *); 199 1.1 kardel static void passwd (struct parse *, FILE *); 200 1.1 kardel static void hostnames (struct parse *, FILE *); 201 1.1 kardel static void setdebug (struct parse *, FILE *); 202 1.1 kardel static void quit (struct parse *, FILE *); 203 1.1 kardel static void version (struct parse *, FILE *); 204 1.1 kardel static void raw (struct parse *, FILE *); 205 1.1 kardel static void cooked (struct parse *, FILE *); 206 1.1 kardel static void authenticate (struct parse *, FILE *); 207 1.1 kardel static void ntpversion (struct parse *, FILE *); 208 1.1.1.5 christos static void warning (const char *, ...) 209 1.1.1.5 christos __attribute__((__format__(__printf__, 1, 2))); 210 1.1.1.5 christos static void error (const char *, ...) 211 1.1.1.5 christos __attribute__((__format__(__printf__, 1, 2))); 212 1.1 kardel static u_long getkeyid (const char *); 213 1.1 kardel static void atoascii (const char *, size_t, char *, size_t); 214 1.1.1.9 christos static void cookedprint (int, size_t, const char *, int, int, FILE *); 215 1.1.1.9 christos static void rawprint (int, size_t, const char *, int, int, FILE *); 216 1.1 kardel static void startoutput (void); 217 1.1.1.3 christos static void output (FILE *, const char *, const char *); 218 1.1 kardel static void endoutput (FILE *); 219 1.1 kardel static void outputarr (FILE *, char *, int, l_fp *); 220 1.1 kardel static int assoccmp (const void *, const void *); 221 1.1.1.9 christos static void on_ctrlc (void); 222 1.1.1.3 christos u_short varfmt (const char *); 223 1.1.1.3 christos 224 1.1 kardel void ntpq_custom_opt_handler (tOptions *, tOptDesc *); 225 1.1 kardel 226 1.1.1.6 christos #ifdef OPENSSL 227 1.1.1.6 christos # ifdef HAVE_EVP_MD_DO_ALL_SORTED 228 1.1.1.6 christos static void list_md_fn(const EVP_MD *m, const char *from, 229 1.1.1.6 christos const char *to, void *arg ); 230 1.1.1.6 christos # endif 231 1.1.1.6 christos #endif 232 1.1.1.6 christos static char *list_digest_names(void); 233 1.1 kardel 234 1.1 kardel /* 235 1.1 kardel * Built-in commands we understand 236 1.1 kardel */ 237 1.1 kardel struct xcmd builtins[] = { 238 1.1 kardel { "?", help, { OPT|NTP_STR, NO, NO, NO }, 239 1.1 kardel { "command", "", "", "" }, 240 1.1 kardel "tell the use and syntax of commands" }, 241 1.1 kardel { "help", help, { OPT|NTP_STR, NO, NO, NO }, 242 1.1 kardel { "command", "", "", "" }, 243 1.1 kardel "tell the use and syntax of commands" }, 244 1.1 kardel { "timeout", timeout, { OPT|NTP_UINT, NO, NO, NO }, 245 1.1 kardel { "msec", "", "", "" }, 246 1.1 kardel "set the primary receive time out" }, 247 1.1 kardel { "delay", auth_delay, { OPT|NTP_INT, NO, NO, NO }, 248 1.1 kardel { "msec", "", "", "" }, 249 1.1 kardel "set the delay added to encryption time stamps" }, 250 1.1 kardel { "host", host, { OPT|NTP_STR, OPT|NTP_STR, NO, NO }, 251 1.1 kardel { "-4|-6", "hostname", "", "" }, 252 1.1 kardel "specify the host whose NTP server we talk to" }, 253 1.1 kardel { "poll", ntp_poll, { OPT|NTP_UINT, OPT|NTP_STR, NO, NO }, 254 1.1 kardel { "n", "verbose", "", "" }, 255 1.1 kardel "poll an NTP server in client mode `n' times" }, 256 1.1.1.3 christos { "passwd", passwd, { OPT|NTP_STR, NO, NO, NO }, 257 1.1 kardel { "", "", "", "" }, 258 1.1 kardel "specify a password to use for authenticated requests"}, 259 1.1 kardel { "hostnames", hostnames, { OPT|NTP_STR, NO, NO, NO }, 260 1.1 kardel { "yes|no", "", "", "" }, 261 1.1 kardel "specify whether hostnames or net numbers are printed"}, 262 1.1 kardel { "debug", setdebug, { OPT|NTP_STR, NO, NO, NO }, 263 1.1 kardel { "no|more|less", "", "", "" }, 264 1.1 kardel "set/change debugging level" }, 265 1.1 kardel { "quit", quit, { NO, NO, NO, NO }, 266 1.1 kardel { "", "", "", "" }, 267 1.1 kardel "exit ntpq" }, 268 1.1 kardel { "exit", quit, { NO, NO, NO, NO }, 269 1.1 kardel { "", "", "", "" }, 270 1.1 kardel "exit ntpq" }, 271 1.1 kardel { "keyid", keyid, { OPT|NTP_UINT, NO, NO, NO }, 272 1.1 kardel { "key#", "", "", "" }, 273 1.1 kardel "set keyid to use for authenticated requests" }, 274 1.1 kardel { "version", version, { NO, NO, NO, NO }, 275 1.1 kardel { "", "", "", "" }, 276 1.1 kardel "print version number" }, 277 1.1 kardel { "raw", raw, { NO, NO, NO, NO }, 278 1.1 kardel { "", "", "", "" }, 279 1.1 kardel "do raw mode variable output" }, 280 1.1 kardel { "cooked", cooked, { NO, NO, NO, NO }, 281 1.1 kardel { "", "", "", "" }, 282 1.1 kardel "do cooked mode variable output" }, 283 1.1 kardel { "authenticate", authenticate, { OPT|NTP_STR, NO, NO, NO }, 284 1.1 kardel { "yes|no", "", "", "" }, 285 1.1 kardel "always authenticate requests to this server" }, 286 1.1 kardel { "ntpversion", ntpversion, { OPT|NTP_UINT, NO, NO, NO }, 287 1.1 kardel { "version number", "", "", "" }, 288 1.1 kardel "set the NTP version number to use for requests" }, 289 1.1 kardel { "keytype", keytype, { OPT|NTP_STR, NO, NO, NO }, 290 1.1.1.6 christos { "key type %s", "", "", "" }, 291 1.1.1.6 christos NULL }, 292 1.1 kardel { 0, 0, { NO, NO, NO, NO }, 293 1.1 kardel { "", "", "", "" }, "" } 294 1.1 kardel }; 295 1.1 kardel 296 1.1 kardel 297 1.1 kardel /* 298 1.1 kardel * Default values we use. 299 1.1 kardel */ 300 1.1 kardel #define DEFHOST "localhost" /* default host name */ 301 1.1.1.3 christos #define DEFTIMEOUT 5 /* wait 5 seconds for 1st pkt */ 302 1.1.1.3 christos #define DEFSTIMEOUT 3 /* and 3 more for each additional */ 303 1.1.1.3 christos /* 304 1.1.1.3 christos * Requests are automatically retried once, so total timeout with no 305 1.1.1.3 christos * response is a bit over 2 * DEFTIMEOUT, or 10 seconds. At the other 306 1.1.1.3 christos * extreme, a request eliciting 32 packets of responses each for some 307 1.1.1.3 christos * reason nearly DEFSTIMEOUT seconds after the prior in that series, 308 1.1.1.3 christos * with a single packet dropped, would take around 32 * DEFSTIMEOUT, or 309 1.1.1.3 christos * 93 seconds to fail each of two times, or 186 seconds. 310 1.1.1.3 christos * Some commands involve a series of requests, such as "peers" and 311 1.1.1.3 christos * "mrulist", so the cumulative timeouts are even longer for those. 312 1.1.1.3 christos */ 313 1.1 kardel #define DEFDELAY 0x51EB852 /* 20 milliseconds, l_fp fraction */ 314 1.1 kardel #define LENHOSTNAME 256 /* host name is 256 characters long */ 315 1.1 kardel #define MAXCMDS 100 /* maximum commands on cmd line */ 316 1.1 kardel #define MAXHOSTS 200 /* maximum hosts on cmd line */ 317 1.1 kardel #define MAXLINE 512 /* maximum line length */ 318 1.1 kardel #define MAXTOKENS (1+MAXARGS+2) /* maximum number of usable tokens */ 319 1.1 kardel #define MAXVARLEN 256 /* maximum length of a variable name */ 320 1.1.1.3 christos #define MAXVALLEN 2048 /* maximum length of a variable value */ 321 1.1 kardel #define MAXOUTLINE 72 /* maximum length of an output line */ 322 1.1 kardel #define SCREENWIDTH 76 /* nominal screen width in columns */ 323 1.1 kardel 324 1.1 kardel /* 325 1.1 kardel * Some variables used and manipulated locally 326 1.1 kardel */ 327 1.1 kardel struct sock_timeval tvout = { DEFTIMEOUT, 0 }; /* time out for reads */ 328 1.1 kardel struct sock_timeval tvsout = { DEFSTIMEOUT, 0 };/* secondary time out */ 329 1.1 kardel l_fp delay_time; /* delay time */ 330 1.1 kardel char currenthost[LENHOSTNAME]; /* current host name */ 331 1.1.1.2 kardel int currenthostisnum; /* is prior text from IP? */ 332 1.1.1.5 christos struct sockaddr_in hostaddr; /* host address */ 333 1.1 kardel int showhostnames = 1; /* show host names by default */ 334 1.1.1.4 christos int wideremote = 0; /* show wide remote names? */ 335 1.1 kardel 336 1.1 kardel int ai_fam_templ; /* address family */ 337 1.1 kardel int ai_fam_default; /* default address family */ 338 1.1 kardel SOCKET sockfd; /* fd socket is opened on */ 339 1.1 kardel int havehost = 0; /* set to 1 when host open */ 340 1.1 kardel int s_port = 0; 341 1.1 kardel struct servent *server_entry = NULL; /* server entry for ntp */ 342 1.1 kardel 343 1.1 kardel 344 1.1 kardel /* 345 1.1 kardel * Sequence number used for requests. It is incremented before 346 1.1 kardel * it is used. 347 1.1 kardel */ 348 1.1 kardel u_short sequence; 349 1.1 kardel 350 1.1 kardel /* 351 1.1 kardel * Holds data returned from queries. Declare buffer long to be sure of 352 1.1 kardel * alignment. 353 1.1 kardel */ 354 1.1 kardel #define DATASIZE (MAXFRAGS*480) /* maximum amount of data */ 355 1.1 kardel long pktdata[DATASIZE/sizeof(long)]; 356 1.1 kardel 357 1.1 kardel /* 358 1.1.1.3 christos * assoc_cache[] is a dynamic array which allows references to 359 1.1.1.3 christos * associations using &1 ... &N for n associations, avoiding manual 360 1.1.1.3 christos * lookup of the current association IDs for a given ntpd. It also 361 1.1.1.3 christos * caches the status word for each association, retrieved incidentally. 362 1.1.1.3 christos */ 363 1.1.1.3 christos struct association * assoc_cache; 364 1.1.1.3 christos u_int assoc_cache_slots;/* count of allocated array entries */ 365 1.1.1.3 christos u_int numassoc; /* number of cached associations */ 366 1.1 kardel 367 1.1 kardel /* 368 1.1 kardel * For commands typed on the command line (with the -c option) 369 1.1 kardel */ 370 1.1 kardel int numcmds = 0; 371 1.1 kardel const char *ccmds[MAXCMDS]; 372 1.1 kardel #define ADDCMD(cp) if (numcmds < MAXCMDS) ccmds[numcmds++] = (cp) 373 1.1 kardel 374 1.1 kardel /* 375 1.1 kardel * When multiple hosts are specified. 376 1.1 kardel */ 377 1.1 kardel 378 1.1.1.3 christos u_int numhosts; 379 1.1.1.3 christos 380 1.1.1.3 christos chost chosts[MAXHOSTS]; 381 1.1.1.3 christos #define ADDHOST(cp) \ 382 1.1.1.3 christos do { \ 383 1.1.1.3 christos if (numhosts < MAXHOSTS) { \ 384 1.1.1.3 christos chosts[numhosts].name = (cp); \ 385 1.1.1.3 christos chosts[numhosts].fam = ai_fam_templ; \ 386 1.1.1.3 christos numhosts++; \ 387 1.1.1.3 christos } \ 388 1.1.1.3 christos } while (0) 389 1.1 kardel 390 1.1 kardel /* 391 1.1 kardel * Macro definitions we use 392 1.1 kardel */ 393 1.1 kardel #define ISSPACE(c) ((c) == ' ' || (c) == '\t') 394 1.1 kardel #define ISEOL(c) ((c) == '\n' || (c) == '\r' || (c) == '\0') 395 1.1 kardel #define STREQ(a, b) (*(a) == *(b) && strcmp((a), (b)) == 0) 396 1.1 kardel 397 1.1 kardel /* 398 1.1 kardel * Jump buffer for longjumping back to the command level 399 1.1 kardel */ 400 1.1 kardel jmp_buf interrupt_buf; 401 1.1 kardel 402 1.1 kardel /* 403 1.1 kardel * Points at file being currently printed into 404 1.1 kardel */ 405 1.1 kardel FILE *current_output; 406 1.1 kardel 407 1.1 kardel /* 408 1.1 kardel * Command table imported from ntpdc_ops.c 409 1.1 kardel */ 410 1.1 kardel extern struct xcmd opcmds[]; 411 1.1 kardel 412 1.1.1.8 christos char const *progname; 413 1.1 kardel 414 1.1 kardel #ifdef NO_MAIN_ALLOWED 415 1.1 kardel #ifndef BUILD_AS_LIB 416 1.1 kardel CALL(ntpq,"ntpq",ntpqmain); 417 1.1 kardel 418 1.1 kardel void clear_globals(void) 419 1.1 kardel { 420 1.1 kardel extern int ntp_optind; 421 1.1 kardel showhostnames = 0; /* don'tshow host names by default */ 422 1.1 kardel ntp_optind = 0; 423 1.1 kardel server_entry = NULL; /* server entry for ntp */ 424 1.1 kardel havehost = 0; /* set to 1 when host open */ 425 1.1 kardel numassoc = 0; /* number of cached associations */ 426 1.1 kardel numcmds = 0; 427 1.1 kardel numhosts = 0; 428 1.1 kardel } 429 1.1 kardel #endif /* !BUILD_AS_LIB */ 430 1.1 kardel #endif /* NO_MAIN_ALLOWED */ 431 1.1 kardel 432 1.1 kardel /* 433 1.1 kardel * main - parse arguments and handle options 434 1.1 kardel */ 435 1.1 kardel #ifndef NO_MAIN_ALLOWED 436 1.1 kardel int 437 1.1 kardel main( 438 1.1 kardel int argc, 439 1.1 kardel char *argv[] 440 1.1 kardel ) 441 1.1 kardel { 442 1.1 kardel return ntpqmain(argc, argv); 443 1.1 kardel } 444 1.1 kardel #endif 445 1.1 kardel 446 1.1 kardel #ifndef BUILD_AS_LIB 447 1.1 kardel int 448 1.1 kardel ntpqmain( 449 1.1 kardel int argc, 450 1.1 kardel char *argv[] 451 1.1 kardel ) 452 1.1 kardel { 453 1.1.1.3 christos u_int ihost; 454 1.1.1.3 christos int icmd; 455 1.1.1.3 christos 456 1.1 kardel 457 1.1 kardel #ifdef SYS_VXWORKS 458 1.1 kardel clear_globals(); 459 1.1 kardel taskPrioritySet(taskIdSelf(), 100 ); 460 1.1 kardel #endif 461 1.1 kardel 462 1.1 kardel delay_time.l_ui = 0; 463 1.1 kardel delay_time.l_uf = DEFDELAY; 464 1.1 kardel 465 1.1 kardel init_lib(); /* sets up ipv4_works, ipv6_works */ 466 1.1 kardel ssl_applink(); 467 1.1.1.3 christos init_auth(); 468 1.1 kardel 469 1.1 kardel /* Check to see if we have IPv6. Otherwise default to IPv4 */ 470 1.1 kardel if (!ipv6_works) 471 1.1 kardel ai_fam_default = AF_INET; 472 1.1 kardel 473 1.1.1.6 christos /* Fixup keytype's help based on available digest names */ 474 1.1.1.6 christos 475 1.1.1.6 christos { 476 1.1.1.6 christos char *list; 477 1.1.1.6 christos char *msg, *fmt; 478 1.1.1.6 christos 479 1.1.1.6 christos list = list_digest_names(); 480 1.1.1.6 christos for (icmd = 0; icmd < sizeof(builtins)/sizeof(builtins[0]); icmd++) { 481 1.1.1.6 christos if (strcmp("keytype", builtins[icmd].keyword) == 0) 482 1.1.1.6 christos break; 483 1.1.1.6 christos } 484 1.1.1.6 christos 485 1.1.1.6 christos /* CID: 1295478 */ 486 1.1.1.6 christos /* This should only "trip" if "keytype" is removed from builtins */ 487 1.1.1.6 christos INSIST(icmd < sizeof(builtins)/sizeof(builtins[0])); 488 1.1.1.6 christos 489 1.1.1.6 christos #ifdef OPENSSL 490 1.1.1.6 christos builtins[icmd].desc[0] = "digest-name"; 491 1.1.1.6 christos fmt = "set key type to use for authenticated requests, one of:%s"; 492 1.1.1.6 christos #else 493 1.1.1.6 christos builtins[icmd].desc[0] = "md5"; 494 1.1.1.6 christos fmt = "set key type to use for authenticated requests (%s)"; 495 1.1.1.6 christos #endif 496 1.1.1.8 christos msg = emalloc(strlen(fmt) + strlen(list) - strlen("%s") +1); 497 1.1.1.6 christos sprintf(msg, fmt, list); 498 1.1.1.6 christos builtins[icmd].comment = msg; 499 1.1.1.6 christos free(list); 500 1.1.1.6 christos } 501 1.1.1.6 christos 502 1.1 kardel progname = argv[0]; 503 1.1 kardel 504 1.1 kardel { 505 1.1.1.2 kardel int optct = ntpOptionProcess(&ntpqOptions, argc, argv); 506 1.1 kardel argc -= optct; 507 1.1 kardel argv += optct; 508 1.1 kardel } 509 1.1 kardel 510 1.1 kardel /* 511 1.1 kardel * Process options other than -c and -p, which are specially 512 1.1 kardel * handled by ntpq_custom_opt_handler(). 513 1.1 kardel */ 514 1.1 kardel 515 1.1.1.3 christos debug = OPT_VALUE_SET_DEBUG_LEVEL; 516 1.1 kardel 517 1.1 kardel if (HAVE_OPT(IPV4)) 518 1.1 kardel ai_fam_templ = AF_INET; 519 1.1 kardel else if (HAVE_OPT(IPV6)) 520 1.1 kardel ai_fam_templ = AF_INET6; 521 1.1 kardel else 522 1.1 kardel ai_fam_templ = ai_fam_default; 523 1.1 kardel 524 1.1 kardel if (HAVE_OPT(INTERACTIVE)) 525 1.1 kardel interactive = 1; 526 1.1 kardel 527 1.1 kardel if (HAVE_OPT(NUMERIC)) 528 1.1 kardel showhostnames = 0; 529 1.1 kardel 530 1.1.1.4 christos if (HAVE_OPT(WIDE)) 531 1.1.1.4 christos wideremote = 1; 532 1.1.1.4 christos 533 1.1 kardel old_rv = HAVE_OPT(OLD_RV); 534 1.1 kardel 535 1.1.1.3 christos if (0 == argc) { 536 1.1 kardel ADDHOST(DEFHOST); 537 1.1 kardel } else { 538 1.1.1.3 christos for (ihost = 0; ihost < (u_int)argc; ihost++) { 539 1.1.1.3 christos if ('-' == *argv[ihost]) { 540 1.1.1.3 christos // 541 1.1.1.3 christos // If I really cared I'd also check: 542 1.1.1.3 christos // 0 == argv[ihost][2] 543 1.1.1.3 christos // 544 1.1.1.3 christos // and there are other cases as well... 545 1.1.1.3 christos // 546 1.1.1.3 christos if ('4' == argv[ihost][1]) { 547 1.1.1.3 christos ai_fam_templ = AF_INET; 548 1.1.1.3 christos continue; 549 1.1.1.3 christos } else if ('6' == argv[ihost][1]) { 550 1.1.1.3 christos ai_fam_templ = AF_INET6; 551 1.1.1.3 christos continue; 552 1.1.1.3 christos } else { 553 1.1.1.3 christos // XXX Throw a usage error 554 1.1.1.3 christos } 555 1.1.1.3 christos } 556 1.1.1.3 christos ADDHOST(argv[ihost]); 557 1.1.1.3 christos } 558 1.1 kardel } 559 1.1 kardel 560 1.1 kardel if (numcmds == 0 && interactive == 0 561 1.1 kardel && isatty(fileno(stdin)) && isatty(fileno(stderr))) { 562 1.1 kardel interactive = 1; 563 1.1 kardel } 564 1.1 kardel 565 1.1.1.9 christos set_ctrl_c_hook(on_ctrlc); 566 1.1 kardel #ifndef SYS_WINNT /* Under NT cannot handle SIGINT, WIN32 spawns a handler */ 567 1.1 kardel if (interactive) 568 1.1.1.9 christos push_ctrl_c_handler(abortcmd); 569 1.1 kardel #endif /* SYS_WINNT */ 570 1.1 kardel 571 1.1 kardel if (numcmds == 0) { 572 1.1.1.3 christos (void) openhost(chosts[0].name, chosts[0].fam); 573 1.1 kardel getcmds(); 574 1.1 kardel } else { 575 1.1 kardel for (ihost = 0; ihost < numhosts; ihost++) { 576 1.1.1.3 christos if (openhost(chosts[ihost].name, chosts[ihost].fam)) 577 1.1 kardel for (icmd = 0; icmd < numcmds; icmd++) 578 1.1 kardel docmd(ccmds[icmd]); 579 1.1 kardel } 580 1.1 kardel } 581 1.1 kardel #ifdef SYS_WINNT 582 1.1 kardel WSACleanup(); 583 1.1 kardel #endif /* SYS_WINNT */ 584 1.1 kardel return 0; 585 1.1 kardel } 586 1.1 kardel #endif /* !BUILD_AS_LIB */ 587 1.1 kardel 588 1.1 kardel /* 589 1.1 kardel * openhost - open a socket to a host 590 1.1 kardel */ 591 1.1 kardel static int 592 1.1 kardel openhost( 593 1.1.1.3 christos const char *hname, 594 1.1.1.3 christos int fam 595 1.1 kardel ) 596 1.1 kardel { 597 1.1.1.3 christos const char svc[] = "ntp"; 598 1.1 kardel char temphost[LENHOSTNAME]; 599 1.1 kardel int a_info, i; 600 1.1.1.3 christos struct addrinfo hints, *ai; 601 1.1.1.3 christos sockaddr_u addr; 602 1.1.1.3 christos size_t octets; 603 1.1 kardel register const char *cp; 604 1.1 kardel char name[LENHOSTNAME]; 605 1.1 kardel 606 1.1 kardel /* 607 1.1 kardel * We need to get by the [] if they were entered 608 1.1 kardel */ 609 1.1.1.3 christos 610 1.1 kardel cp = hname; 611 1.1.1.3 christos 612 1.1 kardel if (*cp == '[') { 613 1.1 kardel cp++; 614 1.1 kardel for (i = 0; *cp && *cp != ']'; cp++, i++) 615 1.1 kardel name[i] = *cp; 616 1.1 kardel if (*cp == ']') { 617 1.1 kardel name[i] = '\0'; 618 1.1 kardel hname = name; 619 1.1 kardel } else { 620 1.1 kardel return 0; 621 1.1 kardel } 622 1.1 kardel } 623 1.1 kardel 624 1.1 kardel /* 625 1.1 kardel * First try to resolve it as an ip address and if that fails, 626 1.1 kardel * do a fullblown (dns) lookup. That way we only use the dns 627 1.1 kardel * when it is needed and work around some implementations that 628 1.1 kardel * will return an "IPv4-mapped IPv6 address" address if you 629 1.1 kardel * give it an IPv4 address to lookup. 630 1.1 kardel */ 631 1.1.1.2 kardel ZERO(hints); 632 1.1.1.3 christos hints.ai_family = fam; 633 1.1 kardel hints.ai_protocol = IPPROTO_UDP; 634 1.1 kardel hints.ai_socktype = SOCK_DGRAM; 635 1.1.1.2 kardel hints.ai_flags = Z_AI_NUMERICHOST; 636 1.1.1.3 christos ai = NULL; 637 1.1 kardel 638 1.1.1.3 christos a_info = getaddrinfo(hname, svc, &hints, &ai); 639 1.1 kardel if (a_info == EAI_NONAME 640 1.1 kardel #ifdef EAI_NODATA 641 1.1 kardel || a_info == EAI_NODATA 642 1.1 kardel #endif 643 1.1 kardel ) { 644 1.1 kardel hints.ai_flags = AI_CANONNAME; 645 1.1 kardel #ifdef AI_ADDRCONFIG 646 1.1 kardel hints.ai_flags |= AI_ADDRCONFIG; 647 1.1 kardel #endif 648 1.1.1.3 christos a_info = getaddrinfo(hname, svc, &hints, &ai); 649 1.1 kardel } 650 1.1 kardel #ifdef AI_ADDRCONFIG 651 1.1 kardel /* Some older implementations don't like AI_ADDRCONFIG. */ 652 1.1 kardel if (a_info == EAI_BADFLAGS) { 653 1.1.1.3 christos hints.ai_flags &= ~AI_ADDRCONFIG; 654 1.1.1.3 christos a_info = getaddrinfo(hname, svc, &hints, &ai); 655 1.1 kardel } 656 1.1 kardel #endif 657 1.1 kardel if (a_info != 0) { 658 1.1.1.3 christos fprintf(stderr, "%s\n", gai_strerror(a_info)); 659 1.1 kardel return 0; 660 1.1 kardel } 661 1.1 kardel 662 1.1.1.3 christos INSIST(ai != NULL); 663 1.1.1.3 christos ZERO(addr); 664 1.1.1.3 christos octets = min(sizeof(addr), ai->ai_addrlen); 665 1.1.1.3 christos memcpy(&addr, ai->ai_addr, octets); 666 1.1.1.3 christos 667 1.1.1.3 christos if (ai->ai_canonname == NULL) { 668 1.1.1.3 christos strlcpy(temphost, stoa(&addr), sizeof(temphost)); 669 1.1.1.2 kardel currenthostisnum = TRUE; 670 1.1 kardel } else { 671 1.1.1.3 christos strlcpy(temphost, ai->ai_canonname, sizeof(temphost)); 672 1.1.1.2 kardel currenthostisnum = FALSE; 673 1.1 kardel } 674 1.1 kardel 675 1.1 kardel if (debug > 2) 676 1.1.1.3 christos printf("Opening host %s (%s)\n", 677 1.1.1.3 christos temphost, 678 1.1.1.3 christos (ai->ai_family == AF_INET) 679 1.1.1.3 christos ? "AF_INET" 680 1.1.1.3 christos : (ai->ai_family == AF_INET6) 681 1.1.1.3 christos ? "AF_INET6" 682 1.1.1.3 christos : "AF-???" 683 1.1.1.3 christos ); 684 1.1 kardel 685 1.1 kardel if (havehost == 1) { 686 1.1 kardel if (debug > 2) 687 1.1 kardel printf("Closing old host %s\n", currenthost); 688 1.1.1.3 christos closesocket(sockfd); 689 1.1 kardel havehost = 0; 690 1.1 kardel } 691 1.1.1.3 christos strlcpy(currenthost, temphost, sizeof(currenthost)); 692 1.1 kardel 693 1.1 kardel /* port maps to the same location in both families */ 694 1.1.1.3 christos s_port = NSRCPORT(&addr); 695 1.1 kardel #ifdef SYS_VXWORKS 696 1.1 kardel ((struct sockaddr_in6 *)&hostaddr)->sin6_port = htons(SERVER_PORT_NUM); 697 1.1 kardel if (ai->ai_family == AF_INET) 698 1.1 kardel *(struct sockaddr_in *)&hostaddr= 699 1.1 kardel *((struct sockaddr_in *)ai->ai_addr); 700 1.1 kardel else 701 1.1 kardel *(struct sockaddr_in6 *)&hostaddr= 702 1.1 kardel *((struct sockaddr_in6 *)ai->ai_addr); 703 1.1 kardel #endif /* SYS_VXWORKS */ 704 1.1 kardel 705 1.1 kardel #ifdef SYS_WINNT 706 1.1 kardel { 707 1.1 kardel int optionValue = SO_SYNCHRONOUS_NONALERT; 708 1.1 kardel int err; 709 1.1 kardel 710 1.1 kardel err = setsockopt(INVALID_SOCKET, SOL_SOCKET, SO_OPENTYPE, 711 1.1 kardel (char *)&optionValue, sizeof(optionValue)); 712 1.1 kardel if (err) { 713 1.1.1.3 christos mfprintf(stderr, 714 1.1.1.3 christos "setsockopt(SO_SYNCHRONOUS_NONALERT)" 715 1.1.1.3 christos " error: %m\n"); 716 1.1.1.3 christos freeaddrinfo(ai); 717 1.1 kardel exit(1); 718 1.1 kardel } 719 1.1 kardel } 720 1.1 kardel #endif /* SYS_WINNT */ 721 1.1 kardel 722 1.1.1.3 christos sockfd = socket(ai->ai_family, ai->ai_socktype, 723 1.1.1.3 christos ai->ai_protocol); 724 1.1 kardel if (sockfd == INVALID_SOCKET) { 725 1.1.1.5 christos error("socket"); 726 1.1.1.3 christos freeaddrinfo(ai); 727 1.1.1.3 christos return 0; 728 1.1 kardel } 729 1.1 kardel 730 1.1.1.3 christos 731 1.1 kardel #ifdef NEED_RCVBUF_SLOP 732 1.1 kardel # ifdef SO_RCVBUF 733 1.1 kardel { int rbufsize = DATASIZE + 2048; /* 2K for slop */ 734 1.1 kardel if (setsockopt(sockfd, SOL_SOCKET, SO_RCVBUF, 735 1.1 kardel &rbufsize, sizeof(int)) == -1) 736 1.1.1.5 christos error("setsockopt"); 737 1.1 kardel } 738 1.1 kardel # endif 739 1.1 kardel #endif 740 1.1 kardel 741 1.1.1.3 christos if 742 1.1 kardel #ifdef SYS_VXWORKS 743 1.1.1.3 christos (connect(sockfd, (struct sockaddr *)&hostaddr, 744 1.1 kardel sizeof(hostaddr)) == -1) 745 1.1 kardel #else 746 1.1.1.3 christos (connect(sockfd, (struct sockaddr *)ai->ai_addr, 747 1.1.1.9 christos ai->ai_addrlen) == -1) 748 1.1 kardel #endif /* SYS_VXWORKS */ 749 1.1.1.9 christos { 750 1.1.1.5 christos error("connect"); 751 1.1 kardel freeaddrinfo(ai); 752 1.1.1.3 christos return 0; 753 1.1.1.3 christos } 754 1.1.1.3 christos freeaddrinfo(ai); 755 1.1 kardel havehost = 1; 756 1.1.1.3 christos numassoc = 0; 757 1.1.1.3 christos 758 1.1 kardel return 1; 759 1.1 kardel } 760 1.1 kardel 761 1.1 kardel 762 1.1.1.3 christos static void 763 1.1.1.3 christos dump_hex_printable( 764 1.1.1.3 christos const void * data, 765 1.1.1.3 christos size_t len 766 1.1.1.3 christos ) 767 1.1.1.3 christos { 768 1.1.1.3 christos const char * cdata; 769 1.1.1.3 christos const char * rowstart; 770 1.1.1.3 christos size_t idx; 771 1.1.1.3 christos size_t rowlen; 772 1.1.1.3 christos u_char uch; 773 1.1.1.3 christos 774 1.1.1.3 christos cdata = data; 775 1.1.1.3 christos while (len > 0) { 776 1.1.1.3 christos rowstart = cdata; 777 1.1.1.3 christos rowlen = min(16, len); 778 1.1.1.3 christos for (idx = 0; idx < rowlen; idx++) { 779 1.1.1.3 christos uch = *(cdata++); 780 1.1.1.3 christos printf("%02x ", uch); 781 1.1.1.3 christos } 782 1.1.1.3 christos for ( ; idx < 16 ; idx++) 783 1.1.1.3 christos printf(" "); 784 1.1.1.3 christos cdata = rowstart; 785 1.1.1.3 christos for (idx = 0; idx < rowlen; idx++) { 786 1.1.1.3 christos uch = *(cdata++); 787 1.1.1.3 christos printf("%c", (isprint(uch)) 788 1.1.1.3 christos ? uch 789 1.1.1.3 christos : '.'); 790 1.1.1.3 christos } 791 1.1.1.3 christos printf("\n"); 792 1.1.1.3 christos len -= rowlen; 793 1.1.1.3 christos } 794 1.1.1.3 christos } 795 1.1.1.3 christos 796 1.1.1.3 christos 797 1.1 kardel /* XXX ELIMINATE sendpkt similar in ntpq.c, ntpdc.c, ntp_io.c, ntptrace.c */ 798 1.1 kardel /* 799 1.1 kardel * sendpkt - send a packet to the remote host 800 1.1 kardel */ 801 1.1 kardel static int 802 1.1 kardel sendpkt( 803 1.1 kardel void * xdata, 804 1.1 kardel size_t xdatalen 805 1.1 kardel ) 806 1.1 kardel { 807 1.1 kardel if (debug >= 3) 808 1.1.1.5 christos printf("Sending %zu octets\n", xdatalen); 809 1.1 kardel 810 1.1.1.9 christos if (send(sockfd, xdata, xdatalen, 0) == -1) { 811 1.1.1.5 christos warning("write to %s failed", currenthost); 812 1.1 kardel return -1; 813 1.1 kardel } 814 1.1 kardel 815 1.1 kardel if (debug >= 4) { 816 1.1.1.3 christos printf("Request packet:\n"); 817 1.1.1.3 christos dump_hex_printable(xdata, xdatalen); 818 1.1 kardel } 819 1.1 kardel return 0; 820 1.1 kardel } 821 1.1 kardel 822 1.1 kardel /* 823 1.1 kardel * getresponse - get a (series of) response packet(s) and return the data 824 1.1 kardel */ 825 1.1 kardel static int 826 1.1 kardel getresponse( 827 1.1 kardel int opcode, 828 1.1 kardel int associd, 829 1.1 kardel u_short *rstatus, 830 1.1.1.9 christos size_t *rsize, 831 1.1.1.2 kardel const char **rdata, 832 1.1 kardel int timeo 833 1.1 kardel ) 834 1.1 kardel { 835 1.1 kardel struct ntp_control rpkt; 836 1.1 kardel struct sock_timeval tvo; 837 1.1 kardel u_short offsets[MAXFRAGS+1]; 838 1.1 kardel u_short counts[MAXFRAGS+1]; 839 1.1 kardel u_short offset; 840 1.1 kardel u_short count; 841 1.1.1.2 kardel size_t numfrags; 842 1.1.1.2 kardel size_t f; 843 1.1.1.2 kardel size_t ff; 844 1.1 kardel int seenlastfrag; 845 1.1 kardel int shouldbesize; 846 1.1 kardel fd_set fds; 847 1.1 kardel int n; 848 1.1.1.3 christos int errcode; 849 1.1 kardel 850 1.1 kardel /* 851 1.1 kardel * This is pretty tricky. We may get between 1 and MAXFRAG packets 852 1.1 kardel * back in response to the request. We peel the data out of 853 1.1 kardel * each packet and collect it in one long block. When the last 854 1.1 kardel * packet in the sequence is received we'll know how much data we 855 1.1 kardel * should have had. Note we use one long time out, should reconsider. 856 1.1 kardel */ 857 1.1 kardel *rsize = 0; 858 1.1 kardel if (rstatus) 859 1.1.1.2 kardel *rstatus = 0; 860 1.1 kardel *rdata = (char *)pktdata; 861 1.1 kardel 862 1.1 kardel numfrags = 0; 863 1.1 kardel seenlastfrag = 0; 864 1.1 kardel 865 1.1 kardel FD_ZERO(&fds); 866 1.1 kardel 867 1.1 kardel /* 868 1.1 kardel * Loop until we have an error or a complete response. Nearly all 869 1.1.1.2 kardel * code paths to loop again use continue. 870 1.1 kardel */ 871 1.1 kardel for (;;) { 872 1.1 kardel 873 1.1 kardel if (numfrags == 0) 874 1.1.1.2 kardel tvo = tvout; 875 1.1 kardel else 876 1.1.1.2 kardel tvo = tvsout; 877 1.1.1.3 christos 878 1.1 kardel FD_SET(sockfd, &fds); 879 1.1.1.9 christos n = select(sockfd+1, &fds, NULL, NULL, &tvo); 880 1.1 kardel if (n == -1) { 881 1.1.1.5 christos warning("select fails"); 882 1.1 kardel return -1; 883 1.1 kardel } 884 1.1 kardel if (n == 0) { 885 1.1 kardel /* 886 1.1 kardel * Timed out. Return what we have 887 1.1 kardel */ 888 1.1 kardel if (numfrags == 0) { 889 1.1 kardel if (timeo) 890 1.1.1.2 kardel fprintf(stderr, 891 1.1.1.2 kardel "%s: timed out, nothing received\n", 892 1.1.1.2 kardel currenthost); 893 1.1 kardel return ERR_TIMEOUT; 894 1.1 kardel } 895 1.1.1.2 kardel if (timeo) 896 1.1.1.2 kardel fprintf(stderr, 897 1.1.1.2 kardel "%s: timed out with incomplete data\n", 898 1.1.1.2 kardel currenthost); 899 1.1.1.2 kardel if (debug) { 900 1.1.1.2 kardel fprintf(stderr, 901 1.1.1.2 kardel "ERR_INCOMPLETE: Received fragments:\n"); 902 1.1.1.2 kardel for (f = 0; f < numfrags; f++) 903 1.1.1.2 kardel fprintf(stderr, 904 1.1.1.2 kardel "%2u: %5d %5d\t%3d octets\n", 905 1.1.1.3 christos (u_int)f, offsets[f], 906 1.1.1.2 kardel offsets[f] + 907 1.1.1.2 kardel counts[f], 908 1.1.1.2 kardel counts[f]); 909 1.1.1.2 kardel fprintf(stderr, 910 1.1.1.2 kardel "last fragment %sreceived\n", 911 1.1.1.2 kardel (seenlastfrag) 912 1.1.1.2 kardel ? "" 913 1.1.1.2 kardel : "not "); 914 1.1.1.2 kardel } 915 1.1.1.2 kardel return ERR_INCOMPLETE; 916 1.1 kardel } 917 1.1 kardel 918 1.1 kardel n = recv(sockfd, (char *)&rpkt, sizeof(rpkt), 0); 919 1.1 kardel if (n == -1) { 920 1.1.1.5 christos warning("read"); 921 1.1 kardel return -1; 922 1.1 kardel } 923 1.1 kardel 924 1.1 kardel if (debug >= 4) { 925 1.1.1.3 christos printf("Response packet:\n"); 926 1.1.1.3 christos dump_hex_printable(&rpkt, n); 927 1.1 kardel } 928 1.1 kardel 929 1.1 kardel /* 930 1.1 kardel * Check for format errors. Bug proofing. 931 1.1 kardel */ 932 1.1.1.5 christos if (n < (int)CTL_HEADER_LEN) { 933 1.1 kardel if (debug) 934 1.1.1.2 kardel printf("Short (%d byte) packet received\n", n); 935 1.1 kardel continue; 936 1.1 kardel } 937 1.1 kardel if (PKT_VERSION(rpkt.li_vn_mode) > NTP_VERSION 938 1.1 kardel || PKT_VERSION(rpkt.li_vn_mode) < NTP_OLDVERSION) { 939 1.1 kardel if (debug) 940 1.1.1.2 kardel printf("Packet received with version %d\n", 941 1.1.1.2 kardel PKT_VERSION(rpkt.li_vn_mode)); 942 1.1 kardel continue; 943 1.1 kardel } 944 1.1 kardel if (PKT_MODE(rpkt.li_vn_mode) != MODE_CONTROL) { 945 1.1 kardel if (debug) 946 1.1.1.2 kardel printf("Packet received with mode %d\n", 947 1.1.1.2 kardel PKT_MODE(rpkt.li_vn_mode)); 948 1.1 kardel continue; 949 1.1 kardel } 950 1.1 kardel if (!CTL_ISRESPONSE(rpkt.r_m_e_op)) { 951 1.1 kardel if (debug) 952 1.1.1.2 kardel printf("Received request packet, wanted response\n"); 953 1.1 kardel continue; 954 1.1 kardel } 955 1.1 kardel 956 1.1 kardel /* 957 1.1 kardel * Check opcode and sequence number for a match. 958 1.1 kardel * Could be old data getting to us. 959 1.1 kardel */ 960 1.1 kardel if (ntohs(rpkt.sequence) != sequence) { 961 1.1 kardel if (debug) 962 1.1.1.2 kardel printf("Received sequnce number %d, wanted %d\n", 963 1.1.1.2 kardel ntohs(rpkt.sequence), sequence); 964 1.1 kardel continue; 965 1.1 kardel } 966 1.1 kardel if (CTL_OP(rpkt.r_m_e_op) != opcode) { 967 1.1 kardel if (debug) 968 1.1 kardel printf( 969 1.1 kardel "Received opcode %d, wanted %d (sequence number okay)\n", 970 1.1 kardel CTL_OP(rpkt.r_m_e_op), opcode); 971 1.1 kardel continue; 972 1.1 kardel } 973 1.1 kardel 974 1.1 kardel /* 975 1.1 kardel * Check the error code. If non-zero, return it. 976 1.1 kardel */ 977 1.1 kardel if (CTL_ISERROR(rpkt.r_m_e_op)) { 978 1.1 kardel errcode = (ntohs(rpkt.status) >> 8) & 0xff; 979 1.1.1.3 christos if (CTL_ISMORE(rpkt.r_m_e_op)) 980 1.1.1.3 christos TRACE(1, ("Error code %d received on not-final packet\n", 981 1.1.1.3 christos errcode)); 982 1.1 kardel if (errcode == CERR_UNSPEC) 983 1.1.1.3 christos return ERR_UNSPEC; 984 1.1 kardel return errcode; 985 1.1 kardel } 986 1.1 kardel 987 1.1 kardel /* 988 1.1 kardel * Check the association ID to make sure it matches what 989 1.1 kardel * we sent. 990 1.1 kardel */ 991 1.1 kardel if (ntohs(rpkt.associd) != associd) { 992 1.1.1.3 christos TRACE(1, ("Association ID %d doesn't match expected %d\n", 993 1.1.1.3 christos ntohs(rpkt.associd), associd)); 994 1.1 kardel /* 995 1.1 kardel * Hack for silly fuzzballs which, at the time of writing, 996 1.1 kardel * return an assID of sys.peer when queried for system variables. 997 1.1 kardel */ 998 1.1 kardel #ifdef notdef 999 1.1 kardel continue; 1000 1.1 kardel #endif 1001 1.1 kardel } 1002 1.1 kardel 1003 1.1 kardel /* 1004 1.1 kardel * Collect offset and count. Make sure they make sense. 1005 1.1 kardel */ 1006 1.1 kardel offset = ntohs(rpkt.offset); 1007 1.1 kardel count = ntohs(rpkt.count); 1008 1.1 kardel 1009 1.1 kardel /* 1010 1.1 kardel * validate received payload size is padded to next 32-bit 1011 1.1 kardel * boundary and no smaller than claimed by rpkt.count 1012 1.1 kardel */ 1013 1.1 kardel if (n & 0x3) { 1014 1.1.1.3 christos TRACE(1, ("Response packet not padded, size = %d\n", 1015 1.1.1.3 christos n)); 1016 1.1 kardel continue; 1017 1.1 kardel } 1018 1.1 kardel 1019 1.1 kardel shouldbesize = (CTL_HEADER_LEN + count + 3) & ~3; 1020 1.1 kardel 1021 1.1 kardel if (n < shouldbesize) { 1022 1.1.1.3 christos printf("Response packet claims %u octets payload, above %ld received\n", 1023 1.1.1.3 christos count, (long)n - CTL_HEADER_LEN); 1024 1.1 kardel return ERR_INCOMPLETE; 1025 1.1 kardel } 1026 1.1 kardel 1027 1.1 kardel if (debug >= 3 && shouldbesize > n) { 1028 1.1 kardel u_int32 key; 1029 1.1 kardel u_int32 *lpkt; 1030 1.1 kardel int maclen; 1031 1.1 kardel 1032 1.1 kardel /* 1033 1.1 kardel * Usually we ignore authentication, but for debugging purposes 1034 1.1 kardel * we watch it here. 1035 1.1 kardel */ 1036 1.1 kardel /* round to 8 octet boundary */ 1037 1.1 kardel shouldbesize = (shouldbesize + 7) & ~7; 1038 1.1 kardel 1039 1.1 kardel maclen = n - shouldbesize; 1040 1.1.1.5 christos if (maclen >= (int)MIN_MAC_LEN) { 1041 1.1 kardel printf( 1042 1.1 kardel "Packet shows signs of authentication (total %d, data %d, mac %d)\n", 1043 1.1 kardel n, shouldbesize, maclen); 1044 1.1 kardel lpkt = (u_int32 *)&rpkt; 1045 1.1 kardel printf("%08lx %08lx %08lx %08lx %08lx %08lx\n", 1046 1.1 kardel (u_long)ntohl(lpkt[(n - maclen)/sizeof(u_int32) - 3]), 1047 1.1 kardel (u_long)ntohl(lpkt[(n - maclen)/sizeof(u_int32) - 2]), 1048 1.1 kardel (u_long)ntohl(lpkt[(n - maclen)/sizeof(u_int32) - 1]), 1049 1.1 kardel (u_long)ntohl(lpkt[(n - maclen)/sizeof(u_int32)]), 1050 1.1 kardel (u_long)ntohl(lpkt[(n - maclen)/sizeof(u_int32) + 1]), 1051 1.1 kardel (u_long)ntohl(lpkt[(n - maclen)/sizeof(u_int32) + 2])); 1052 1.1 kardel key = ntohl(lpkt[(n - maclen) / sizeof(u_int32)]); 1053 1.1 kardel printf("Authenticated with keyid %lu\n", (u_long)key); 1054 1.1 kardel if (key != 0 && key != info_auth_keyid) { 1055 1.1 kardel printf("We don't know that key\n"); 1056 1.1 kardel } else { 1057 1.1 kardel if (authdecrypt(key, (u_int32 *)&rpkt, 1058 1.1 kardel n - maclen, maclen)) { 1059 1.1 kardel printf("Auth okay!\n"); 1060 1.1 kardel } else { 1061 1.1 kardel printf("Auth failed!\n"); 1062 1.1 kardel } 1063 1.1 kardel } 1064 1.1 kardel } 1065 1.1 kardel } 1066 1.1 kardel 1067 1.1.1.3 christos TRACE(2, ("Got packet, size = %d\n", n)); 1068 1.1.1.3 christos if (count > (n - CTL_HEADER_LEN)) { 1069 1.1.1.3 christos TRACE(1, ("Received count of %u octets, data in packet is %ld\n", 1070 1.1.1.3 christos count, (long)n - CTL_HEADER_LEN)); 1071 1.1 kardel continue; 1072 1.1 kardel } 1073 1.1 kardel if (count == 0 && CTL_ISMORE(rpkt.r_m_e_op)) { 1074 1.1.1.3 christos TRACE(1, ("Received count of 0 in non-final fragment\n")); 1075 1.1 kardel continue; 1076 1.1 kardel } 1077 1.1 kardel if (offset + count > sizeof(pktdata)) { 1078 1.1.1.3 christos TRACE(1, ("Offset %u, count %u, too big for buffer\n", 1079 1.1.1.3 christos offset, count)); 1080 1.1 kardel return ERR_TOOMUCH; 1081 1.1 kardel } 1082 1.1 kardel if (seenlastfrag && !CTL_ISMORE(rpkt.r_m_e_op)) { 1083 1.1.1.3 christos TRACE(1, ("Received second last fragment packet\n")); 1084 1.1 kardel continue; 1085 1.1 kardel } 1086 1.1 kardel 1087 1.1 kardel /* 1088 1.1 kardel * So far, so good. Record this fragment, making sure it doesn't 1089 1.1 kardel * overlap anything. 1090 1.1 kardel */ 1091 1.1.1.3 christos TRACE(2, ("Packet okay\n")); 1092 1.1 kardel 1093 1.1 kardel if (numfrags > (MAXFRAGS - 1)) { 1094 1.1.1.3 christos TRACE(2, ("Number of fragments exceeds maximum %d\n", 1095 1.1.1.3 christos MAXFRAGS - 1)); 1096 1.1 kardel return ERR_TOOMUCH; 1097 1.1 kardel } 1098 1.1 kardel 1099 1.1 kardel /* 1100 1.1 kardel * Find the position for the fragment relative to any 1101 1.1 kardel * previously received. 1102 1.1 kardel */ 1103 1.1.1.3 christos for (f = 0; 1104 1.1.1.3 christos f < numfrags && offsets[f] < offset; 1105 1.1.1.2 kardel f++) { 1106 1.1 kardel /* empty body */ ; 1107 1.1 kardel } 1108 1.1 kardel 1109 1.1.1.2 kardel if (f < numfrags && offset == offsets[f]) { 1110 1.1.1.3 christos TRACE(1, ("duplicate %u octets at %u ignored, prior %u at %u\n", 1111 1.1.1.3 christos count, offset, counts[f], offsets[f])); 1112 1.1 kardel continue; 1113 1.1 kardel } 1114 1.1 kardel 1115 1.1.1.2 kardel if (f > 0 && (offsets[f-1] + counts[f-1]) > offset) { 1116 1.1.1.3 christos TRACE(1, ("received frag at %u overlaps with %u octet frag at %u\n", 1117 1.1.1.3 christos offset, counts[f-1], offsets[f-1])); 1118 1.1 kardel continue; 1119 1.1 kardel } 1120 1.1 kardel 1121 1.1.1.2 kardel if (f < numfrags && (offset + count) > offsets[f]) { 1122 1.1.1.3 christos TRACE(1, ("received %u octet frag at %u overlaps with frag at %u\n", 1123 1.1.1.3 christos count, offset, offsets[f])); 1124 1.1 kardel continue; 1125 1.1 kardel } 1126 1.1 kardel 1127 1.1.1.2 kardel for (ff = numfrags; ff > f; ff--) { 1128 1.1.1.2 kardel offsets[ff] = offsets[ff-1]; 1129 1.1.1.2 kardel counts[ff] = counts[ff-1]; 1130 1.1 kardel } 1131 1.1.1.2 kardel offsets[f] = offset; 1132 1.1.1.2 kardel counts[f] = count; 1133 1.1 kardel numfrags++; 1134 1.1 kardel 1135 1.1 kardel /* 1136 1.1 kardel * Got that stuffed in right. Figure out if this was the last. 1137 1.1 kardel * Record status info out of the last packet. 1138 1.1 kardel */ 1139 1.1 kardel if (!CTL_ISMORE(rpkt.r_m_e_op)) { 1140 1.1 kardel seenlastfrag = 1; 1141 1.1 kardel if (rstatus != 0) 1142 1.1.1.2 kardel *rstatus = ntohs(rpkt.status); 1143 1.1 kardel } 1144 1.1 kardel 1145 1.1 kardel /* 1146 1.1 kardel * Copy the data into the data buffer. 1147 1.1 kardel */ 1148 1.1.1.3 christos memcpy((char *)pktdata + offset, &rpkt.u, count); 1149 1.1 kardel 1150 1.1 kardel /* 1151 1.1 kardel * If we've seen the last fragment, look for holes in the sequence. 1152 1.1 kardel * If there aren't any, we're done. 1153 1.1 kardel */ 1154 1.1 kardel if (seenlastfrag && offsets[0] == 0) { 1155 1.1.1.2 kardel for (f = 1; f < numfrags; f++) 1156 1.1.1.2 kardel if (offsets[f-1] + counts[f-1] != 1157 1.1.1.2 kardel offsets[f]) 1158 1.1 kardel break; 1159 1.1.1.2 kardel if (f == numfrags) { 1160 1.1.1.2 kardel *rsize = offsets[f-1] + counts[f-1]; 1161 1.1.1.3 christos TRACE(1, ("%lu packets reassembled into response\n", 1162 1.1.1.3 christos (u_long)numfrags)); 1163 1.1 kardel return 0; 1164 1.1 kardel } 1165 1.1 kardel } 1166 1.1 kardel } /* giant for (;;) collecting response packets */ 1167 1.1 kardel } /* getresponse() */ 1168 1.1 kardel 1169 1.1 kardel 1170 1.1 kardel /* 1171 1.1 kardel * sendrequest - format and send a request packet 1172 1.1 kardel */ 1173 1.1 kardel static int 1174 1.1 kardel sendrequest( 1175 1.1 kardel int opcode, 1176 1.1.1.3 christos associd_t associd, 1177 1.1 kardel int auth, 1178 1.1.1.9 christos size_t qsize, 1179 1.1.1.3 christos const char *qdata 1180 1.1 kardel ) 1181 1.1 kardel { 1182 1.1 kardel struct ntp_control qpkt; 1183 1.1.1.9 christos size_t pktsize; 1184 1.1 kardel u_long key_id; 1185 1.1 kardel char * pass; 1186 1.1.1.9 christos size_t maclen; 1187 1.1 kardel 1188 1.1 kardel /* 1189 1.1 kardel * Check to make sure the data will fit in one packet 1190 1.1 kardel */ 1191 1.1 kardel if (qsize > CTL_MAX_DATA_LEN) { 1192 1.1 kardel fprintf(stderr, 1193 1.1.1.9 christos "***Internal error! qsize (%zu) too large\n", 1194 1.1 kardel qsize); 1195 1.1 kardel return 1; 1196 1.1 kardel } 1197 1.1 kardel 1198 1.1 kardel /* 1199 1.1 kardel * Fill in the packet 1200 1.1 kardel */ 1201 1.1 kardel qpkt.li_vn_mode = PKT_LI_VN_MODE(0, pktversion, MODE_CONTROL); 1202 1.1 kardel qpkt.r_m_e_op = (u_char)(opcode & CTL_OP_MASK); 1203 1.1 kardel qpkt.sequence = htons(sequence); 1204 1.1 kardel qpkt.status = 0; 1205 1.1 kardel qpkt.associd = htons((u_short)associd); 1206 1.1 kardel qpkt.offset = 0; 1207 1.1 kardel qpkt.count = htons((u_short)qsize); 1208 1.1 kardel 1209 1.1 kardel pktsize = CTL_HEADER_LEN; 1210 1.1 kardel 1211 1.1 kardel /* 1212 1.1 kardel * If we have data, copy and pad it out to a 32-bit boundary. 1213 1.1 kardel */ 1214 1.1 kardel if (qsize > 0) { 1215 1.1.1.3 christos memcpy(&qpkt.u, qdata, (size_t)qsize); 1216 1.1 kardel pktsize += qsize; 1217 1.1 kardel while (pktsize & (sizeof(u_int32) - 1)) { 1218 1.1.1.3 christos qpkt.u.data[qsize++] = 0; 1219 1.1 kardel pktsize++; 1220 1.1 kardel } 1221 1.1 kardel } 1222 1.1 kardel 1223 1.1 kardel /* 1224 1.1 kardel * If it isn't authenticated we can just send it. Otherwise 1225 1.1 kardel * we're going to have to think about it a little. 1226 1.1 kardel */ 1227 1.1 kardel if (!auth && !always_auth) { 1228 1.1 kardel return sendpkt(&qpkt, pktsize); 1229 1.1.1.3 christos } 1230 1.1 kardel 1231 1.1 kardel /* 1232 1.1 kardel * Pad out packet to a multiple of 8 octets to be sure 1233 1.1 kardel * receiver can handle it. 1234 1.1 kardel */ 1235 1.1 kardel while (pktsize & 7) { 1236 1.1.1.3 christos qpkt.u.data[qsize++] = 0; 1237 1.1 kardel pktsize++; 1238 1.1 kardel } 1239 1.1 kardel 1240 1.1 kardel /* 1241 1.1 kardel * Get the keyid and the password if we don't have one. 1242 1.1 kardel */ 1243 1.1 kardel if (info_auth_keyid == 0) { 1244 1.1 kardel key_id = getkeyid("Keyid: "); 1245 1.1 kardel if (key_id == 0 || key_id > NTP_MAXKEY) { 1246 1.1.1.3 christos fprintf(stderr, 1247 1.1 kardel "Invalid key identifier\n"); 1248 1.1 kardel return 1; 1249 1.1 kardel } 1250 1.1 kardel info_auth_keyid = key_id; 1251 1.1 kardel } 1252 1.1 kardel if (!authistrusted(info_auth_keyid)) { 1253 1.1.1.2 kardel pass = getpass_keytype(info_auth_keytype); 1254 1.1 kardel if ('\0' == pass[0]) { 1255 1.1 kardel fprintf(stderr, "Invalid password\n"); 1256 1.1 kardel return 1; 1257 1.1 kardel } 1258 1.1 kardel authusekey(info_auth_keyid, info_auth_keytype, 1259 1.1 kardel (u_char *)pass); 1260 1.1 kardel authtrust(info_auth_keyid, 1); 1261 1.1 kardel } 1262 1.1 kardel 1263 1.1 kardel /* 1264 1.1 kardel * Do the encryption. 1265 1.1 kardel */ 1266 1.1 kardel maclen = authencrypt(info_auth_keyid, (void *)&qpkt, pktsize); 1267 1.1.1.3 christos if (!maclen) { 1268 1.1 kardel fprintf(stderr, "Key not found\n"); 1269 1.1 kardel return 1; 1270 1.1 kardel } else if ((size_t)maclen != (info_auth_hashlen + sizeof(keyid_t))) { 1271 1.1 kardel fprintf(stderr, 1272 1.1.1.9 christos "%zu octet MAC, %zu expected with %zu octet digest\n", 1273 1.1.1.5 christos maclen, (info_auth_hashlen + sizeof(keyid_t)), 1274 1.1.1.5 christos info_auth_hashlen); 1275 1.1 kardel return 1; 1276 1.1 kardel } 1277 1.1.1.3 christos 1278 1.1 kardel return sendpkt((char *)&qpkt, pktsize + maclen); 1279 1.1 kardel } 1280 1.1 kardel 1281 1.1 kardel 1282 1.1 kardel /* 1283 1.1.1.2 kardel * show_error_msg - display the error text for a mode 6 error response. 1284 1.1.1.2 kardel */ 1285 1.1.1.2 kardel void 1286 1.1.1.2 kardel show_error_msg( 1287 1.1.1.2 kardel int m6resp, 1288 1.1.1.2 kardel associd_t associd 1289 1.1.1.2 kardel ) 1290 1.1.1.2 kardel { 1291 1.1.1.2 kardel if (numhosts > 1) 1292 1.1.1.2 kardel fprintf(stderr, "server=%s ", currenthost); 1293 1.1.1.2 kardel 1294 1.1.1.2 kardel switch(m6resp) { 1295 1.1.1.2 kardel 1296 1.1.1.2 kardel case CERR_BADFMT: 1297 1.1.1.2 kardel fprintf(stderr, 1298 1.1.1.2 kardel "***Server reports a bad format request packet\n"); 1299 1.1.1.2 kardel break; 1300 1.1.1.2 kardel 1301 1.1.1.2 kardel case CERR_PERMISSION: 1302 1.1.1.2 kardel fprintf(stderr, 1303 1.1.1.2 kardel "***Server disallowed request (authentication?)\n"); 1304 1.1.1.2 kardel break; 1305 1.1.1.2 kardel 1306 1.1.1.2 kardel case CERR_BADOP: 1307 1.1.1.2 kardel fprintf(stderr, 1308 1.1.1.2 kardel "***Server reports a bad opcode in request\n"); 1309 1.1.1.2 kardel break; 1310 1.1.1.2 kardel 1311 1.1.1.2 kardel case CERR_BADASSOC: 1312 1.1.1.2 kardel fprintf(stderr, 1313 1.1.1.2 kardel "***Association ID %d unknown to server\n", 1314 1.1.1.2 kardel associd); 1315 1.1.1.2 kardel break; 1316 1.1.1.2 kardel 1317 1.1.1.2 kardel case CERR_UNKNOWNVAR: 1318 1.1.1.2 kardel fprintf(stderr, 1319 1.1.1.2 kardel "***A request variable unknown to the server\n"); 1320 1.1.1.2 kardel break; 1321 1.1.1.2 kardel 1322 1.1.1.2 kardel case CERR_BADVALUE: 1323 1.1.1.2 kardel fprintf(stderr, 1324 1.1.1.2 kardel "***Server indicates a request variable was bad\n"); 1325 1.1.1.2 kardel break; 1326 1.1.1.2 kardel 1327 1.1.1.2 kardel case ERR_UNSPEC: 1328 1.1.1.2 kardel fprintf(stderr, 1329 1.1.1.2 kardel "***Server returned an unspecified error\n"); 1330 1.1.1.2 kardel break; 1331 1.1.1.2 kardel 1332 1.1.1.2 kardel case ERR_TIMEOUT: 1333 1.1.1.2 kardel fprintf(stderr, "***Request timed out\n"); 1334 1.1.1.2 kardel break; 1335 1.1.1.2 kardel 1336 1.1.1.2 kardel case ERR_INCOMPLETE: 1337 1.1.1.2 kardel fprintf(stderr, 1338 1.1.1.2 kardel "***Response from server was incomplete\n"); 1339 1.1.1.2 kardel break; 1340 1.1.1.2 kardel 1341 1.1.1.2 kardel case ERR_TOOMUCH: 1342 1.1.1.2 kardel fprintf(stderr, 1343 1.1.1.2 kardel "***Buffer size exceeded for returned data\n"); 1344 1.1.1.2 kardel break; 1345 1.1.1.2 kardel 1346 1.1.1.2 kardel default: 1347 1.1.1.2 kardel fprintf(stderr, 1348 1.1.1.2 kardel "***Server returns unknown error code %d\n", 1349 1.1.1.2 kardel m6resp); 1350 1.1.1.2 kardel } 1351 1.1.1.2 kardel } 1352 1.1.1.2 kardel 1353 1.1.1.2 kardel /* 1354 1.1.1.2 kardel * doquery - send a request and process the response, displaying 1355 1.1.1.2 kardel * error messages for any error responses. 1356 1.1 kardel */ 1357 1.1 kardel int 1358 1.1 kardel doquery( 1359 1.1 kardel int opcode, 1360 1.1.1.2 kardel associd_t associd, 1361 1.1 kardel int auth, 1362 1.1.1.9 christos size_t qsize, 1363 1.1.1.3 christos const char *qdata, 1364 1.1 kardel u_short *rstatus, 1365 1.1.1.9 christos size_t *rsize, 1366 1.1.1.2 kardel const char **rdata 1367 1.1.1.2 kardel ) 1368 1.1.1.2 kardel { 1369 1.1.1.2 kardel return doqueryex(opcode, associd, auth, qsize, qdata, rstatus, 1370 1.1.1.2 kardel rsize, rdata, FALSE); 1371 1.1.1.2 kardel } 1372 1.1.1.2 kardel 1373 1.1.1.2 kardel 1374 1.1.1.2 kardel /* 1375 1.1.1.2 kardel * doqueryex - send a request and process the response, optionally 1376 1.1.1.2 kardel * displaying error messages for any error responses. 1377 1.1.1.2 kardel */ 1378 1.1.1.2 kardel int 1379 1.1.1.2 kardel doqueryex( 1380 1.1.1.2 kardel int opcode, 1381 1.1.1.2 kardel associd_t associd, 1382 1.1.1.2 kardel int auth, 1383 1.1.1.9 christos size_t qsize, 1384 1.1.1.3 christos const char *qdata, 1385 1.1.1.2 kardel u_short *rstatus, 1386 1.1.1.9 christos size_t *rsize, 1387 1.1.1.2 kardel const char **rdata, 1388 1.1.1.2 kardel int quiet 1389 1.1 kardel ) 1390 1.1 kardel { 1391 1.1 kardel int res; 1392 1.1 kardel int done; 1393 1.1 kardel 1394 1.1 kardel /* 1395 1.1 kardel * Check to make sure host is open 1396 1.1 kardel */ 1397 1.1 kardel if (!havehost) { 1398 1.1.1.2 kardel fprintf(stderr, "***No host open, use `host' command\n"); 1399 1.1 kardel return -1; 1400 1.1 kardel } 1401 1.1 kardel 1402 1.1 kardel done = 0; 1403 1.1 kardel sequence++; 1404 1.1 kardel 1405 1.1 kardel again: 1406 1.1 kardel /* 1407 1.1 kardel * send a request 1408 1.1 kardel */ 1409 1.1 kardel res = sendrequest(opcode, associd, auth, qsize, qdata); 1410 1.1 kardel if (res != 0) 1411 1.1.1.2 kardel return res; 1412 1.1.1.3 christos 1413 1.1 kardel /* 1414 1.1 kardel * Get the response. If we got a standard error, print a message 1415 1.1 kardel */ 1416 1.1 kardel res = getresponse(opcode, associd, rstatus, rsize, rdata, done); 1417 1.1 kardel 1418 1.1 kardel if (res > 0) { 1419 1.1 kardel if (!done && (res == ERR_TIMEOUT || res == ERR_INCOMPLETE)) { 1420 1.1 kardel if (res == ERR_INCOMPLETE) { 1421 1.1 kardel /* 1422 1.1 kardel * better bump the sequence so we don't 1423 1.1 kardel * get confused about differing fragments. 1424 1.1 kardel */ 1425 1.1 kardel sequence++; 1426 1.1 kardel } 1427 1.1 kardel done = 1; 1428 1.1 kardel goto again; 1429 1.1 kardel } 1430 1.1.1.2 kardel if (!quiet) 1431 1.1.1.2 kardel show_error_msg(res, associd); 1432 1.1.1.2 kardel 1433 1.1 kardel } 1434 1.1 kardel return res; 1435 1.1 kardel } 1436 1.1 kardel 1437 1.1 kardel 1438 1.1 kardel #ifndef BUILD_AS_LIB 1439 1.1 kardel /* 1440 1.1 kardel * getcmds - read commands from the standard input and execute them 1441 1.1 kardel */ 1442 1.1 kardel static void 1443 1.1 kardel getcmds(void) 1444 1.1 kardel { 1445 1.1 kardel char * line; 1446 1.1 kardel int count; 1447 1.1 kardel 1448 1.1 kardel ntp_readline_init(interactive ? prompt : NULL); 1449 1.1 kardel 1450 1.1 kardel for (;;) { 1451 1.1 kardel line = ntp_readline(&count); 1452 1.1 kardel if (NULL == line) 1453 1.1 kardel break; 1454 1.1 kardel docmd(line); 1455 1.1 kardel free(line); 1456 1.1 kardel } 1457 1.1 kardel 1458 1.1 kardel ntp_readline_uninit(); 1459 1.1 kardel } 1460 1.1 kardel #endif /* !BUILD_AS_LIB */ 1461 1.1 kardel 1462 1.1 kardel 1463 1.1 kardel #if !defined(SYS_WINNT) && !defined(BUILD_AS_LIB) 1464 1.1 kardel /* 1465 1.1 kardel * abortcmd - catch interrupts and abort the current command 1466 1.1 kardel */ 1467 1.1.1.9 christos static int 1468 1.1.1.9 christos abortcmd(void) 1469 1.1 kardel { 1470 1.1 kardel if (current_output == stdout) 1471 1.1.1.9 christos (void) fflush(stdout); 1472 1.1 kardel putc('\n', stderr); 1473 1.1 kardel (void) fflush(stderr); 1474 1.1.1.9 christos if (jump) { 1475 1.1.1.9 christos jump = 0; 1476 1.1.1.9 christos longjmp(interrupt_buf, 1); 1477 1.1.1.9 christos } 1478 1.1.1.9 christos return TRUE; 1479 1.1 kardel } 1480 1.1 kardel #endif /* !SYS_WINNT && !BUILD_AS_LIB */ 1481 1.1 kardel 1482 1.1 kardel 1483 1.1 kardel #ifndef BUILD_AS_LIB 1484 1.1 kardel /* 1485 1.1 kardel * docmd - decode the command line and execute a command 1486 1.1 kardel */ 1487 1.1 kardel static void 1488 1.1 kardel docmd( 1489 1.1 kardel const char *cmdline 1490 1.1 kardel ) 1491 1.1 kardel { 1492 1.1 kardel char *tokens[1+MAXARGS+2]; 1493 1.1 kardel struct parse pcmd; 1494 1.1 kardel int ntok; 1495 1.1 kardel static int i; 1496 1.1 kardel struct xcmd *xcmd; 1497 1.1 kardel 1498 1.1 kardel /* 1499 1.1 kardel * Tokenize the command line. If nothing on it, return. 1500 1.1 kardel */ 1501 1.1 kardel tokenize(cmdline, tokens, &ntok); 1502 1.1 kardel if (ntok == 0) 1503 1.1 kardel return; 1504 1.1.1.3 christos 1505 1.1 kardel /* 1506 1.1 kardel * Find the appropriate command description. 1507 1.1 kardel */ 1508 1.1 kardel i = findcmd(tokens[0], builtins, opcmds, &xcmd); 1509 1.1 kardel if (i == 0) { 1510 1.1 kardel (void) fprintf(stderr, "***Command `%s' unknown\n", 1511 1.1 kardel tokens[0]); 1512 1.1 kardel return; 1513 1.1 kardel } else if (i >= 2) { 1514 1.1 kardel (void) fprintf(stderr, "***Command `%s' ambiguous\n", 1515 1.1 kardel tokens[0]); 1516 1.1 kardel return; 1517 1.1 kardel } 1518 1.1.1.3 christos 1519 1.1.1.3 christos /* Warn about ignored extra args */ 1520 1.1.1.3 christos for (i = MAXARGS + 1; i < ntok ; ++i) { 1521 1.1.1.3 christos fprintf(stderr, "***Extra arg `%s' ignored\n", tokens[i]); 1522 1.1.1.3 christos } 1523 1.1.1.3 christos 1524 1.1 kardel /* 1525 1.1 kardel * Save the keyword, then walk through the arguments, interpreting 1526 1.1 kardel * as we go. 1527 1.1 kardel */ 1528 1.1 kardel pcmd.keyword = tokens[0]; 1529 1.1 kardel pcmd.nargs = 0; 1530 1.1 kardel for (i = 0; i < MAXARGS && xcmd->arg[i] != NO; i++) { 1531 1.1 kardel if ((i+1) >= ntok) { 1532 1.1 kardel if (!(xcmd->arg[i] & OPT)) { 1533 1.1 kardel printusage(xcmd, stderr); 1534 1.1 kardel return; 1535 1.1 kardel } 1536 1.1 kardel break; 1537 1.1 kardel } 1538 1.1 kardel if ((xcmd->arg[i] & OPT) && (*tokens[i+1] == '>')) 1539 1.1 kardel break; 1540 1.1 kardel if (!getarg(tokens[i+1], (int)xcmd->arg[i], &pcmd.argval[i])) 1541 1.1 kardel return; 1542 1.1 kardel pcmd.nargs++; 1543 1.1 kardel } 1544 1.1 kardel 1545 1.1 kardel i++; 1546 1.1 kardel if (i < ntok && *tokens[i] == '>') { 1547 1.1 kardel char *fname; 1548 1.1 kardel 1549 1.1 kardel if (*(tokens[i]+1) != '\0') 1550 1.1 kardel fname = tokens[i]+1; 1551 1.1 kardel else if ((i+1) < ntok) 1552 1.1 kardel fname = tokens[i+1]; 1553 1.1 kardel else { 1554 1.1 kardel (void) fprintf(stderr, "***No file for redirect\n"); 1555 1.1 kardel return; 1556 1.1 kardel } 1557 1.1 kardel 1558 1.1 kardel current_output = fopen(fname, "w"); 1559 1.1 kardel if (current_output == NULL) { 1560 1.1 kardel (void) fprintf(stderr, "***Error opening %s: ", fname); 1561 1.1 kardel perror(""); 1562 1.1 kardel return; 1563 1.1 kardel } 1564 1.1 kardel i = 1; /* flag we need a close */ 1565 1.1 kardel } else { 1566 1.1 kardel current_output = stdout; 1567 1.1 kardel i = 0; /* flag no close */ 1568 1.1 kardel } 1569 1.1 kardel 1570 1.1 kardel if (interactive && setjmp(interrupt_buf)) { 1571 1.1 kardel jump = 0; 1572 1.1 kardel return; 1573 1.1 kardel } else { 1574 1.1 kardel jump++; 1575 1.1 kardel (xcmd->handler)(&pcmd, current_output); 1576 1.1 kardel jump = 0; /* HMS: 961106: was after fclose() */ 1577 1.1 kardel if (i) (void) fclose(current_output); 1578 1.1 kardel } 1579 1.1.1.3 christos 1580 1.1.1.3 christos return; 1581 1.1 kardel } 1582 1.1 kardel 1583 1.1 kardel 1584 1.1 kardel /* 1585 1.1 kardel * tokenize - turn a command line into tokens 1586 1.1 kardel * 1587 1.1.1.3 christos * SK: Modified to allow a quoted string 1588 1.1 kardel * 1589 1.1 kardel * HMS: If the first character of the first token is a ':' then (after 1590 1.1 kardel * eating inter-token whitespace) the 2nd token is the rest of the line. 1591 1.1 kardel */ 1592 1.1 kardel 1593 1.1 kardel static void 1594 1.1 kardel tokenize( 1595 1.1 kardel const char *line, 1596 1.1 kardel char **tokens, 1597 1.1 kardel int *ntok 1598 1.1 kardel ) 1599 1.1 kardel { 1600 1.1 kardel register const char *cp; 1601 1.1 kardel register char *sp; 1602 1.1 kardel static char tspace[MAXLINE]; 1603 1.1 kardel 1604 1.1 kardel sp = tspace; 1605 1.1 kardel cp = line; 1606 1.1 kardel for (*ntok = 0; *ntok < MAXTOKENS; (*ntok)++) { 1607 1.1 kardel tokens[*ntok] = sp; 1608 1.1 kardel 1609 1.1 kardel /* Skip inter-token whitespace */ 1610 1.1 kardel while (ISSPACE(*cp)) 1611 1.1 kardel cp++; 1612 1.1 kardel 1613 1.1 kardel /* If we're at EOL we're done */ 1614 1.1 kardel if (ISEOL(*cp)) 1615 1.1 kardel break; 1616 1.1 kardel 1617 1.1 kardel /* If this is the 2nd token and the first token begins 1618 1.1 kardel * with a ':', then just grab to EOL. 1619 1.1 kardel */ 1620 1.1 kardel 1621 1.1 kardel if (*ntok == 1 && tokens[0][0] == ':') { 1622 1.1 kardel do { 1623 1.1.1.4 christos if (sp - tspace >= MAXLINE) 1624 1.1.1.4 christos goto toobig; 1625 1.1 kardel *sp++ = *cp++; 1626 1.1 kardel } while (!ISEOL(*cp)); 1627 1.1 kardel } 1628 1.1 kardel 1629 1.1 kardel /* Check if this token begins with a double quote. 1630 1.1 kardel * If yes, continue reading till the next double quote 1631 1.1 kardel */ 1632 1.1 kardel else if (*cp == '\"') { 1633 1.1 kardel ++cp; 1634 1.1 kardel do { 1635 1.1.1.4 christos if (sp - tspace >= MAXLINE) 1636 1.1.1.4 christos goto toobig; 1637 1.1 kardel *sp++ = *cp++; 1638 1.1 kardel } while ((*cp != '\"') && !ISEOL(*cp)); 1639 1.1 kardel /* HMS: a missing closing " should be an error */ 1640 1.1 kardel } 1641 1.1 kardel else { 1642 1.1 kardel do { 1643 1.1.1.4 christos if (sp - tspace >= MAXLINE) 1644 1.1.1.4 christos goto toobig; 1645 1.1 kardel *sp++ = *cp++; 1646 1.1 kardel } while ((*cp != '\"') && !ISSPACE(*cp) && !ISEOL(*cp)); 1647 1.1 kardel /* HMS: Why check for a " in the previous line? */ 1648 1.1 kardel } 1649 1.1 kardel 1650 1.1.1.4 christos if (sp - tspace >= MAXLINE) 1651 1.1.1.4 christos goto toobig; 1652 1.1 kardel *sp++ = '\0'; 1653 1.1 kardel } 1654 1.1.1.4 christos return; 1655 1.1.1.4 christos 1656 1.1.1.4 christos toobig: 1657 1.1.1.4 christos *ntok = 0; 1658 1.1.1.4 christos fprintf(stderr, 1659 1.1.1.4 christos "***Line `%s' is too big\n", 1660 1.1.1.4 christos line); 1661 1.1.1.4 christos return; 1662 1.1 kardel } 1663 1.1 kardel 1664 1.1 kardel 1665 1.1 kardel /* 1666 1.1 kardel * getarg - interpret an argument token 1667 1.1 kardel */ 1668 1.1 kardel static int 1669 1.1 kardel getarg( 1670 1.1.1.3 christos const char *str, 1671 1.1 kardel int code, 1672 1.1 kardel arg_v *argp 1673 1.1 kardel ) 1674 1.1 kardel { 1675 1.1.1.3 christos u_long ul; 1676 1.1 kardel 1677 1.1 kardel switch (code & ~OPT) { 1678 1.1.1.3 christos case NTP_STR: 1679 1.1 kardel argp->string = str; 1680 1.1 kardel break; 1681 1.1.1.3 christos 1682 1.1.1.3 christos case NTP_ADD: 1683 1.1.1.3 christos if (!getnetnum(str, &argp->netnum, NULL, 0)) 1684 1.1 kardel return 0; 1685 1.1 kardel break; 1686 1.1.1.3 christos 1687 1.1.1.3 christos case NTP_UINT: 1688 1.1.1.3 christos if ('&' == str[0]) { 1689 1.1.1.3 christos if (!atouint(&str[1], &ul)) { 1690 1.1.1.3 christos fprintf(stderr, 1691 1.1.1.3 christos "***Association index `%s' invalid/undecodable\n", 1692 1.1.1.3 christos str); 1693 1.1 kardel return 0; 1694 1.1 kardel } 1695 1.1.1.3 christos if (0 == numassoc) { 1696 1.1.1.3 christos dogetassoc(stdout); 1697 1.1.1.3 christos if (0 == numassoc) { 1698 1.1.1.3 christos fprintf(stderr, 1699 1.1.1.3 christos "***No associations found, `%s' unknown\n", 1700 1.1.1.3 christos str); 1701 1.1 kardel return 0; 1702 1.1 kardel } 1703 1.1 kardel } 1704 1.1.1.3 christos ul = min(ul, numassoc); 1705 1.1.1.3 christos argp->uval = assoc_cache[ul - 1].assid; 1706 1.1 kardel break; 1707 1.1 kardel } 1708 1.1.1.3 christos if (!atouint(str, &argp->uval)) { 1709 1.1.1.3 christos fprintf(stderr, "***Illegal unsigned value %s\n", 1710 1.1.1.3 christos str); 1711 1.1.1.3 christos return 0; 1712 1.1 kardel } 1713 1.1.1.3 christos break; 1714 1.1 kardel 1715 1.1.1.3 christos case NTP_INT: 1716 1.1.1.3 christos if (!atoint(str, &argp->ival)) { 1717 1.1.1.3 christos fprintf(stderr, "***Illegal integer value %s\n", 1718 1.1.1.3 christos str); 1719 1.1.1.3 christos return 0; 1720 1.1 kardel } 1721 1.1 kardel break; 1722 1.1.1.3 christos 1723 1.1.1.3 christos case IP_VERSION: 1724 1.1.1.3 christos if (!strcmp("-6", str)) { 1725 1.1.1.3 christos argp->ival = 6; 1726 1.1.1.3 christos } else if (!strcmp("-4", str)) { 1727 1.1.1.3 christos argp->ival = 4; 1728 1.1.1.3 christos } else { 1729 1.1.1.3 christos fprintf(stderr, "***Version must be either 4 or 6\n"); 1730 1.1 kardel return 0; 1731 1.1 kardel } 1732 1.1 kardel break; 1733 1.1 kardel } 1734 1.1 kardel 1735 1.1 kardel return 1; 1736 1.1 kardel } 1737 1.1 kardel #endif /* !BUILD_AS_LIB */ 1738 1.1 kardel 1739 1.1 kardel 1740 1.1 kardel /* 1741 1.1 kardel * findcmd - find a command in a command description table 1742 1.1 kardel */ 1743 1.1 kardel static int 1744 1.1 kardel findcmd( 1745 1.1.1.3 christos const char * str, 1746 1.1.1.3 christos struct xcmd * clist1, 1747 1.1.1.3 christos struct xcmd * clist2, 1748 1.1.1.3 christos struct xcmd ** cmd 1749 1.1 kardel ) 1750 1.1 kardel { 1751 1.1.1.3 christos struct xcmd *cl; 1752 1.1.1.9 christos size_t clen; 1753 1.1 kardel int nmatch; 1754 1.1 kardel struct xcmd *nearmatch = NULL; 1755 1.1 kardel struct xcmd *clist; 1756 1.1 kardel 1757 1.1 kardel clen = strlen(str); 1758 1.1 kardel nmatch = 0; 1759 1.1 kardel if (clist1 != 0) 1760 1.1 kardel clist = clist1; 1761 1.1 kardel else if (clist2 != 0) 1762 1.1 kardel clist = clist2; 1763 1.1 kardel else 1764 1.1 kardel return 0; 1765 1.1 kardel 1766 1.1 kardel again: 1767 1.1 kardel for (cl = clist; cl->keyword != 0; cl++) { 1768 1.1 kardel /* do a first character check, for efficiency */ 1769 1.1 kardel if (*str != *(cl->keyword)) 1770 1.1 kardel continue; 1771 1.1 kardel if (strncmp(str, cl->keyword, (unsigned)clen) == 0) { 1772 1.1 kardel /* 1773 1.1 kardel * Could be extact match, could be approximate. 1774 1.1 kardel * Is exact if the length of the keyword is the 1775 1.1 kardel * same as the str. 1776 1.1 kardel */ 1777 1.1 kardel if (*((cl->keyword) + clen) == '\0') { 1778 1.1 kardel *cmd = cl; 1779 1.1 kardel return 1; 1780 1.1 kardel } 1781 1.1 kardel nmatch++; 1782 1.1 kardel nearmatch = cl; 1783 1.1 kardel } 1784 1.1 kardel } 1785 1.1 kardel 1786 1.1 kardel /* 1787 1.1 kardel * See if there is more to do. If so, go again. Sorry about the 1788 1.1 kardel * goto, too much looking at BSD sources... 1789 1.1 kardel */ 1790 1.1 kardel if (clist == clist1 && clist2 != 0) { 1791 1.1 kardel clist = clist2; 1792 1.1 kardel goto again; 1793 1.1 kardel } 1794 1.1 kardel 1795 1.1 kardel /* 1796 1.1 kardel * If we got extactly 1 near match, use it, else return number 1797 1.1 kardel * of matches. 1798 1.1 kardel */ 1799 1.1 kardel if (nmatch == 1) { 1800 1.1 kardel *cmd = nearmatch; 1801 1.1 kardel return 1; 1802 1.1 kardel } 1803 1.1 kardel return nmatch; 1804 1.1 kardel } 1805 1.1 kardel 1806 1.1 kardel 1807 1.1 kardel /* 1808 1.1 kardel * getnetnum - given a host name, return its net number 1809 1.1 kardel * and (optional) full name 1810 1.1 kardel */ 1811 1.1 kardel int 1812 1.1 kardel getnetnum( 1813 1.1 kardel const char *hname, 1814 1.1 kardel sockaddr_u *num, 1815 1.1 kardel char *fullhost, 1816 1.1 kardel int af 1817 1.1 kardel ) 1818 1.1 kardel { 1819 1.1 kardel struct addrinfo hints, *ai = NULL; 1820 1.1 kardel 1821 1.1.1.2 kardel ZERO(hints); 1822 1.1 kardel hints.ai_flags = AI_CANONNAME; 1823 1.1 kardel #ifdef AI_ADDRCONFIG 1824 1.1 kardel hints.ai_flags |= AI_ADDRCONFIG; 1825 1.1 kardel #endif 1826 1.1.1.3 christos 1827 1.1.1.2 kardel /* 1828 1.1.1.2 kardel * decodenetnum only works with addresses, but handles syntax 1829 1.1.1.2 kardel * that getaddrinfo doesn't: [2001::1]:1234 1830 1.1.1.2 kardel */ 1831 1.1 kardel if (decodenetnum(hname, num)) { 1832 1.1.1.2 kardel if (fullhost != NULL) 1833 1.1.1.2 kardel getnameinfo(&num->sa, SOCKLEN(num), fullhost, 1834 1.1.1.2 kardel LENHOSTNAME, NULL, 0, 0); 1835 1.1 kardel return 1; 1836 1.1 kardel } else if (getaddrinfo(hname, "ntp", &hints, &ai) == 0) { 1837 1.1.1.3 christos INSIST(sizeof(*num) >= ai->ai_addrlen); 1838 1.1.1.2 kardel memcpy(num, ai->ai_addr, ai->ai_addrlen); 1839 1.1.1.2 kardel if (fullhost != NULL) { 1840 1.1.1.3 christos if (ai->ai_canonname != NULL) 1841 1.1.1.3 christos strlcpy(fullhost, ai->ai_canonname, 1842 1.1.1.2 kardel LENHOSTNAME); 1843 1.1.1.3 christos else 1844 1.1.1.2 kardel getnameinfo(&num->sa, SOCKLEN(num), 1845 1.1.1.2 kardel fullhost, LENHOSTNAME, NULL, 1846 1.1.1.2 kardel 0, 0); 1847 1.1.1.2 kardel } 1848 1.1.1.3 christos freeaddrinfo(ai); 1849 1.1 kardel return 1; 1850 1.1 kardel } 1851 1.1.1.2 kardel fprintf(stderr, "***Can't find host %s\n", hname); 1852 1.1.1.2 kardel 1853 1.1.1.2 kardel return 0; 1854 1.1 kardel } 1855 1.1 kardel 1856 1.1.1.3 christos 1857 1.1 kardel /* 1858 1.1 kardel * nntohost - convert network number to host name. This routine enforces 1859 1.1 kardel * the showhostnames setting. 1860 1.1 kardel */ 1861 1.1.1.3 christos const char * 1862 1.1 kardel nntohost( 1863 1.1 kardel sockaddr_u *netnum 1864 1.1 kardel ) 1865 1.1 kardel { 1866 1.1.1.2 kardel return nntohost_col(netnum, LIB_BUFLENGTH - 1, FALSE); 1867 1.1.1.2 kardel } 1868 1.1.1.2 kardel 1869 1.1.1.2 kardel 1870 1.1.1.2 kardel /* 1871 1.1.1.2 kardel * nntohost_col - convert network number to host name in fixed width. 1872 1.1.1.2 kardel * This routine enforces the showhostnames setting. 1873 1.1.1.2 kardel * When displaying hostnames longer than the width, 1874 1.1.1.2 kardel * the first part of the hostname is displayed. When 1875 1.1.1.2 kardel * displaying numeric addresses longer than the width, 1876 1.1.1.2 kardel * Such as IPv6 addresses, the caller decides whether 1877 1.1.1.2 kardel * the first or last of the numeric address is used. 1878 1.1.1.2 kardel */ 1879 1.1.1.3 christos const char * 1880 1.1.1.2 kardel nntohost_col( 1881 1.1.1.2 kardel sockaddr_u * addr, 1882 1.1.1.2 kardel size_t width, 1883 1.1.1.2 kardel int preserve_lowaddrbits 1884 1.1.1.2 kardel ) 1885 1.1.1.2 kardel { 1886 1.1.1.2 kardel const char * out; 1887 1.1.1.2 kardel 1888 1.1.1.3 christos if (!showhostnames || SOCK_UNSPEC(addr)) { 1889 1.1.1.2 kardel if (preserve_lowaddrbits) 1890 1.1.1.2 kardel out = trunc_left(stoa(addr), width); 1891 1.1.1.2 kardel else 1892 1.1.1.2 kardel out = trunc_right(stoa(addr), width); 1893 1.1.1.2 kardel } else if (ISREFCLOCKADR(addr)) { 1894 1.1.1.2 kardel out = refnumtoa(addr); 1895 1.1.1.2 kardel } else { 1896 1.1.1.2 kardel out = trunc_right(socktohost(addr), width); 1897 1.1.1.2 kardel } 1898 1.1.1.2 kardel return out; 1899 1.1 kardel } 1900 1.1 kardel 1901 1.1 kardel 1902 1.1 kardel /* 1903 1.1.1.3 christos * nntohostp() is the same as nntohost() plus a :port suffix 1904 1.1.1.3 christos */ 1905 1.1.1.3 christos const char * 1906 1.1.1.3 christos nntohostp( 1907 1.1.1.3 christos sockaddr_u *netnum 1908 1.1.1.3 christos ) 1909 1.1.1.3 christos { 1910 1.1.1.3 christos const char * hostn; 1911 1.1.1.3 christos char * buf; 1912 1.1.1.3 christos 1913 1.1.1.3 christos if (!showhostnames || SOCK_UNSPEC(netnum)) 1914 1.1.1.3 christos return sptoa(netnum); 1915 1.1.1.3 christos else if (ISREFCLOCKADR(netnum)) 1916 1.1.1.3 christos return refnumtoa(netnum); 1917 1.1.1.3 christos 1918 1.1.1.3 christos hostn = socktohost(netnum); 1919 1.1.1.3 christos LIB_GETBUF(buf); 1920 1.1.1.3 christos snprintf(buf, LIB_BUFLENGTH, "%s:%u", hostn, SRCPORT(netnum)); 1921 1.1.1.3 christos 1922 1.1.1.3 christos return buf; 1923 1.1.1.3 christos } 1924 1.1.1.3 christos 1925 1.1.1.3 christos /* 1926 1.1 kardel * rtdatetolfp - decode an RT-11 date into an l_fp 1927 1.1 kardel */ 1928 1.1 kardel static int 1929 1.1 kardel rtdatetolfp( 1930 1.1 kardel char *str, 1931 1.1 kardel l_fp *lfp 1932 1.1 kardel ) 1933 1.1 kardel { 1934 1.1 kardel register char *cp; 1935 1.1 kardel register int i; 1936 1.1 kardel struct calendar cal; 1937 1.1 kardel char buf[4]; 1938 1.1 kardel 1939 1.1 kardel cal.yearday = 0; 1940 1.1 kardel 1941 1.1 kardel /* 1942 1.1 kardel * An RT-11 date looks like: 1943 1.1 kardel * 1944 1.1 kardel * d[d]-Mth-y[y] hh:mm:ss 1945 1.1 kardel * 1946 1.1 kardel * (No docs, but assume 4-digit years are also legal...) 1947 1.1 kardel * 1948 1.1 kardel * d[d]-Mth-y[y[y[y]]] hh:mm:ss 1949 1.1 kardel */ 1950 1.1 kardel cp = str; 1951 1.1 kardel if (!isdigit((int)*cp)) { 1952 1.1 kardel if (*cp == '-') { 1953 1.1 kardel /* 1954 1.1 kardel * Catch special case 1955 1.1 kardel */ 1956 1.1 kardel L_CLR(lfp); 1957 1.1 kardel return 1; 1958 1.1 kardel } 1959 1.1 kardel return 0; 1960 1.1 kardel } 1961 1.1 kardel 1962 1.1 kardel cal.monthday = (u_char) (*cp++ - '0'); /* ascii dependent */ 1963 1.1 kardel if (isdigit((int)*cp)) { 1964 1.1 kardel cal.monthday = (u_char)((cal.monthday << 3) + (cal.monthday << 1)); 1965 1.1 kardel cal.monthday = (u_char)(cal.monthday + *cp++ - '0'); 1966 1.1 kardel } 1967 1.1 kardel 1968 1.1 kardel if (*cp++ != '-') 1969 1.1 kardel return 0; 1970 1.1.1.3 christos 1971 1.1 kardel for (i = 0; i < 3; i++) 1972 1.1 kardel buf[i] = *cp++; 1973 1.1 kardel buf[3] = '\0'; 1974 1.1 kardel 1975 1.1 kardel for (i = 0; i < 12; i++) 1976 1.1 kardel if (STREQ(buf, months[i])) 1977 1.1 kardel break; 1978 1.1 kardel if (i == 12) 1979 1.1 kardel return 0; 1980 1.1 kardel cal.month = (u_char)(i + 1); 1981 1.1 kardel 1982 1.1 kardel if (*cp++ != '-') 1983 1.1 kardel return 0; 1984 1.1.1.3 christos 1985 1.1 kardel if (!isdigit((int)*cp)) 1986 1.1 kardel return 0; 1987 1.1 kardel cal.year = (u_short)(*cp++ - '0'); 1988 1.1 kardel if (isdigit((int)*cp)) { 1989 1.1 kardel cal.year = (u_short)((cal.year << 3) + (cal.year << 1)); 1990 1.1 kardel cal.year = (u_short)(*cp++ - '0'); 1991 1.1 kardel } 1992 1.1 kardel if (isdigit((int)*cp)) { 1993 1.1 kardel cal.year = (u_short)((cal.year << 3) + (cal.year << 1)); 1994 1.1 kardel cal.year = (u_short)(cal.year + *cp++ - '0'); 1995 1.1 kardel } 1996 1.1 kardel if (isdigit((int)*cp)) { 1997 1.1 kardel cal.year = (u_short)((cal.year << 3) + (cal.year << 1)); 1998 1.1 kardel cal.year = (u_short)(cal.year + *cp++ - '0'); 1999 1.1 kardel } 2000 1.1 kardel 2001 1.1 kardel /* 2002 1.1 kardel * Catch special case. If cal.year == 0 this is a zero timestamp. 2003 1.1 kardel */ 2004 1.1 kardel if (cal.year == 0) { 2005 1.1 kardel L_CLR(lfp); 2006 1.1 kardel return 1; 2007 1.1 kardel } 2008 1.1 kardel 2009 1.1 kardel if (*cp++ != ' ' || !isdigit((int)*cp)) 2010 1.1 kardel return 0; 2011 1.1 kardel cal.hour = (u_char)(*cp++ - '0'); 2012 1.1 kardel if (isdigit((int)*cp)) { 2013 1.1 kardel cal.hour = (u_char)((cal.hour << 3) + (cal.hour << 1)); 2014 1.1 kardel cal.hour = (u_char)(cal.hour + *cp++ - '0'); 2015 1.1 kardel } 2016 1.1 kardel 2017 1.1 kardel if (*cp++ != ':' || !isdigit((int)*cp)) 2018 1.1 kardel return 0; 2019 1.1 kardel cal.minute = (u_char)(*cp++ - '0'); 2020 1.1 kardel if (isdigit((int)*cp)) { 2021 1.1 kardel cal.minute = (u_char)((cal.minute << 3) + (cal.minute << 1)); 2022 1.1 kardel cal.minute = (u_char)(cal.minute + *cp++ - '0'); 2023 1.1 kardel } 2024 1.1 kardel 2025 1.1 kardel if (*cp++ != ':' || !isdigit((int)*cp)) 2026 1.1 kardel return 0; 2027 1.1 kardel cal.second = (u_char)(*cp++ - '0'); 2028 1.1 kardel if (isdigit((int)*cp)) { 2029 1.1 kardel cal.second = (u_char)((cal.second << 3) + (cal.second << 1)); 2030 1.1 kardel cal.second = (u_char)(cal.second + *cp++ - '0'); 2031 1.1 kardel } 2032 1.1 kardel 2033 1.1 kardel /* 2034 1.1 kardel * For RT-11, 1972 seems to be the pivot year 2035 1.1 kardel */ 2036 1.1 kardel if (cal.year < 72) 2037 1.1 kardel cal.year += 2000; 2038 1.1 kardel if (cal.year < 100) 2039 1.1 kardel cal.year += 1900; 2040 1.1 kardel 2041 1.1 kardel lfp->l_ui = caltontp(&cal); 2042 1.1 kardel lfp->l_uf = 0; 2043 1.1 kardel return 1; 2044 1.1 kardel } 2045 1.1 kardel 2046 1.1 kardel 2047 1.1 kardel /* 2048 1.1 kardel * decodets - decode a timestamp into an l_fp format number, with 2049 1.1 kardel * consideration of fuzzball formats. 2050 1.1 kardel */ 2051 1.1 kardel int 2052 1.1 kardel decodets( 2053 1.1 kardel char *str, 2054 1.1 kardel l_fp *lfp 2055 1.1 kardel ) 2056 1.1 kardel { 2057 1.1.1.2 kardel char *cp; 2058 1.1.1.2 kardel char buf[30]; 2059 1.1.1.2 kardel size_t b; 2060 1.1.1.2 kardel 2061 1.1 kardel /* 2062 1.1 kardel * If it starts with a 0x, decode as hex. 2063 1.1 kardel */ 2064 1.1 kardel if (*str == '0' && (*(str+1) == 'x' || *(str+1) == 'X')) 2065 1.1 kardel return hextolfp(str+2, lfp); 2066 1.1 kardel 2067 1.1 kardel /* 2068 1.1 kardel * If it starts with a '"', try it as an RT-11 date. 2069 1.1 kardel */ 2070 1.1 kardel if (*str == '"') { 2071 1.1.1.2 kardel cp = str + 1; 2072 1.1.1.2 kardel b = 0; 2073 1.1.1.2 kardel while ('"' != *cp && '\0' != *cp && 2074 1.1.1.2 kardel b < COUNTOF(buf) - 1) 2075 1.1.1.2 kardel buf[b++] = *cp++; 2076 1.1.1.2 kardel buf[b] = '\0'; 2077 1.1 kardel return rtdatetolfp(buf, lfp); 2078 1.1 kardel } 2079 1.1 kardel 2080 1.1 kardel /* 2081 1.1 kardel * Might still be hex. Check out the first character. Talk 2082 1.1 kardel * about heuristics! 2083 1.1 kardel */ 2084 1.1 kardel if ((*str >= 'A' && *str <= 'F') || (*str >= 'a' && *str <= 'f')) 2085 1.1 kardel return hextolfp(str, lfp); 2086 1.1 kardel 2087 1.1 kardel /* 2088 1.1 kardel * Try it as a decimal. If this fails, try as an unquoted 2089 1.1 kardel * RT-11 date. This code should go away eventually. 2090 1.1 kardel */ 2091 1.1 kardel if (atolfp(str, lfp)) 2092 1.1 kardel return 1; 2093 1.1 kardel 2094 1.1 kardel return rtdatetolfp(str, lfp); 2095 1.1 kardel } 2096 1.1 kardel 2097 1.1 kardel 2098 1.1 kardel /* 2099 1.1 kardel * decodetime - decode a time value. It should be in milliseconds 2100 1.1 kardel */ 2101 1.1 kardel int 2102 1.1 kardel decodetime( 2103 1.1 kardel char *str, 2104 1.1 kardel l_fp *lfp 2105 1.1 kardel ) 2106 1.1 kardel { 2107 1.1 kardel return mstolfp(str, lfp); 2108 1.1 kardel } 2109 1.1 kardel 2110 1.1 kardel 2111 1.1 kardel /* 2112 1.1 kardel * decodeint - decode an integer 2113 1.1 kardel */ 2114 1.1 kardel int 2115 1.1 kardel decodeint( 2116 1.1 kardel char *str, 2117 1.1 kardel long *val 2118 1.1 kardel ) 2119 1.1 kardel { 2120 1.1 kardel if (*str == '0') { 2121 1.1 kardel if (*(str+1) == 'x' || *(str+1) == 'X') 2122 1.1 kardel return hextoint(str+2, (u_long *)val); 2123 1.1 kardel return octtoint(str, (u_long *)val); 2124 1.1 kardel } 2125 1.1 kardel return atoint(str, val); 2126 1.1 kardel } 2127 1.1 kardel 2128 1.1 kardel 2129 1.1 kardel /* 2130 1.1 kardel * decodeuint - decode an unsigned integer 2131 1.1 kardel */ 2132 1.1 kardel int 2133 1.1 kardel decodeuint( 2134 1.1 kardel char *str, 2135 1.1 kardel u_long *val 2136 1.1 kardel ) 2137 1.1 kardel { 2138 1.1 kardel if (*str == '0') { 2139 1.1 kardel if (*(str + 1) == 'x' || *(str + 1) == 'X') 2140 1.1 kardel return (hextoint(str + 2, val)); 2141 1.1 kardel return (octtoint(str, val)); 2142 1.1 kardel } 2143 1.1 kardel return (atouint(str, val)); 2144 1.1 kardel } 2145 1.1 kardel 2146 1.1 kardel 2147 1.1 kardel /* 2148 1.1 kardel * decodearr - decode an array of time values 2149 1.1 kardel */ 2150 1.1 kardel static int 2151 1.1 kardel decodearr( 2152 1.1 kardel char *str, 2153 1.1 kardel int *narr, 2154 1.1 kardel l_fp *lfparr 2155 1.1 kardel ) 2156 1.1 kardel { 2157 1.1 kardel register char *cp, *bp; 2158 1.1 kardel register l_fp *lfp; 2159 1.1 kardel char buf[60]; 2160 1.1 kardel 2161 1.1 kardel lfp = lfparr; 2162 1.1 kardel cp = str; 2163 1.1 kardel *narr = 0; 2164 1.1 kardel 2165 1.1 kardel while (*narr < 8) { 2166 1.1 kardel while (isspace((int)*cp)) 2167 1.1 kardel cp++; 2168 1.1 kardel if (*cp == '\0') 2169 1.1 kardel break; 2170 1.1 kardel 2171 1.1 kardel bp = buf; 2172 1.1 kardel while (!isspace((int)*cp) && *cp != '\0') 2173 1.1 kardel *bp++ = *cp++; 2174 1.1 kardel *bp++ = '\0'; 2175 1.1 kardel 2176 1.1 kardel if (!decodetime(buf, lfp)) 2177 1.1 kardel return 0; 2178 1.1 kardel (*narr)++; 2179 1.1 kardel lfp++; 2180 1.1 kardel } 2181 1.1 kardel return 1; 2182 1.1 kardel } 2183 1.1 kardel 2184 1.1 kardel 2185 1.1 kardel /* 2186 1.1 kardel * Finally, the built in command handlers 2187 1.1 kardel */ 2188 1.1 kardel 2189 1.1 kardel /* 2190 1.1 kardel * help - tell about commands, or details of a particular command 2191 1.1 kardel */ 2192 1.1 kardel static void 2193 1.1 kardel help( 2194 1.1 kardel struct parse *pcmd, 2195 1.1 kardel FILE *fp 2196 1.1 kardel ) 2197 1.1 kardel { 2198 1.1 kardel struct xcmd *xcp = NULL; /* quiet warning */ 2199 1.1.1.3 christos const char *cmd; 2200 1.1 kardel const char *list[100]; 2201 1.1.1.2 kardel size_t word, words; 2202 1.1.1.2 kardel size_t row, rows; 2203 1.1.1.2 kardel size_t col, cols; 2204 1.1.1.2 kardel size_t length; 2205 1.1 kardel 2206 1.1 kardel if (pcmd->nargs == 0) { 2207 1.1 kardel words = 0; 2208 1.1.1.2 kardel for (xcp = builtins; xcp->keyword != NULL; xcp++) { 2209 1.1.1.3 christos if (*(xcp->keyword) != '?' && 2210 1.1.1.3 christos words < COUNTOF(list)) 2211 1.1 kardel list[words++] = xcp->keyword; 2212 1.1 kardel } 2213 1.1.1.2 kardel for (xcp = opcmds; xcp->keyword != NULL; xcp++) 2214 1.1.1.3 christos if (words < COUNTOF(list)) 2215 1.1.1.3 christos list[words++] = xcp->keyword; 2216 1.1 kardel 2217 1.1.1.3 christos qsort((void *)list, words, sizeof(list[0]), helpsort); 2218 1.1 kardel col = 0; 2219 1.1 kardel for (word = 0; word < words; word++) { 2220 1.1.1.3 christos length = strlen(list[word]); 2221 1.1.1.2 kardel col = max(col, length); 2222 1.1 kardel } 2223 1.1 kardel 2224 1.1 kardel cols = SCREENWIDTH / ++col; 2225 1.1 kardel rows = (words + cols - 1) / cols; 2226 1.1 kardel 2227 1.1.1.2 kardel fprintf(fp, "ntpq commands:\n"); 2228 1.1 kardel 2229 1.1 kardel for (row = 0; row < rows; row++) { 2230 1.1.1.2 kardel for (word = row; word < words; word += rows) 2231 1.1.1.3 christos fprintf(fp, "%-*.*s", (int)col, 2232 1.1.1.3 christos (int)col - 1, list[word]); 2233 1.1.1.2 kardel fprintf(fp, "\n"); 2234 1.1 kardel } 2235 1.1 kardel } else { 2236 1.1 kardel cmd = pcmd->argval[0].string; 2237 1.1 kardel words = findcmd(cmd, builtins, opcmds, &xcp); 2238 1.1 kardel if (words == 0) { 2239 1.1.1.2 kardel fprintf(stderr, 2240 1.1.1.2 kardel "Command `%s' is unknown\n", cmd); 2241 1.1 kardel return; 2242 1.1 kardel } else if (words >= 2) { 2243 1.1.1.2 kardel fprintf(stderr, 2244 1.1.1.2 kardel "Command `%s' is ambiguous\n", cmd); 2245 1.1 kardel return; 2246 1.1 kardel } 2247 1.1.1.2 kardel fprintf(fp, "function: %s\n", xcp->comment); 2248 1.1 kardel printusage(xcp, fp); 2249 1.1 kardel } 2250 1.1 kardel } 2251 1.1 kardel 2252 1.1 kardel 2253 1.1 kardel /* 2254 1.1 kardel * helpsort - do hostname qsort comparisons 2255 1.1 kardel */ 2256 1.1 kardel static int 2257 1.1 kardel helpsort( 2258 1.1 kardel const void *t1, 2259 1.1 kardel const void *t2 2260 1.1 kardel ) 2261 1.1 kardel { 2262 1.1.1.2 kardel const char * const * name1 = t1; 2263 1.1.1.2 kardel const char * const * name2 = t2; 2264 1.1 kardel 2265 1.1 kardel return strcmp(*name1, *name2); 2266 1.1 kardel } 2267 1.1 kardel 2268 1.1 kardel 2269 1.1 kardel /* 2270 1.1 kardel * printusage - print usage information for a command 2271 1.1 kardel */ 2272 1.1 kardel static void 2273 1.1 kardel printusage( 2274 1.1 kardel struct xcmd *xcp, 2275 1.1 kardel FILE *fp 2276 1.1 kardel ) 2277 1.1 kardel { 2278 1.1 kardel register int i; 2279 1.1 kardel 2280 1.1.1.3 christos /* XXX: Do we need to warn about extra args here too? */ 2281 1.1.1.3 christos 2282 1.1 kardel (void) fprintf(fp, "usage: %s", xcp->keyword); 2283 1.1 kardel for (i = 0; i < MAXARGS && xcp->arg[i] != NO; i++) { 2284 1.1 kardel if (xcp->arg[i] & OPT) 2285 1.1 kardel (void) fprintf(fp, " [ %s ]", xcp->desc[i]); 2286 1.1 kardel else 2287 1.1 kardel (void) fprintf(fp, " %s", xcp->desc[i]); 2288 1.1 kardel } 2289 1.1 kardel (void) fprintf(fp, "\n"); 2290 1.1 kardel } 2291 1.1 kardel 2292 1.1 kardel 2293 1.1 kardel /* 2294 1.1 kardel * timeout - set time out time 2295 1.1 kardel */ 2296 1.1 kardel static void 2297 1.1 kardel timeout( 2298 1.1 kardel struct parse *pcmd, 2299 1.1 kardel FILE *fp 2300 1.1 kardel ) 2301 1.1 kardel { 2302 1.1 kardel int val; 2303 1.1 kardel 2304 1.1 kardel if (pcmd->nargs == 0) { 2305 1.1 kardel val = (int)tvout.tv_sec * 1000 + tvout.tv_usec / 1000; 2306 1.1 kardel (void) fprintf(fp, "primary timeout %d ms\n", val); 2307 1.1 kardel } else { 2308 1.1 kardel tvout.tv_sec = pcmd->argval[0].uval / 1000; 2309 1.1 kardel tvout.tv_usec = (pcmd->argval[0].uval - ((long)tvout.tv_sec * 1000)) 2310 1.1 kardel * 1000; 2311 1.1 kardel } 2312 1.1 kardel } 2313 1.1 kardel 2314 1.1 kardel 2315 1.1 kardel /* 2316 1.1 kardel * auth_delay - set delay for auth requests 2317 1.1 kardel */ 2318 1.1 kardel static void 2319 1.1 kardel auth_delay( 2320 1.1 kardel struct parse *pcmd, 2321 1.1 kardel FILE *fp 2322 1.1 kardel ) 2323 1.1 kardel { 2324 1.1 kardel int isneg; 2325 1.1 kardel u_long val; 2326 1.1 kardel 2327 1.1 kardel if (pcmd->nargs == 0) { 2328 1.1 kardel val = delay_time.l_ui * 1000 + delay_time.l_uf / 4294967; 2329 1.1 kardel (void) fprintf(fp, "delay %lu ms\n", val); 2330 1.1 kardel } else { 2331 1.1 kardel if (pcmd->argval[0].ival < 0) { 2332 1.1 kardel isneg = 1; 2333 1.1 kardel val = (u_long)(-pcmd->argval[0].ival); 2334 1.1 kardel } else { 2335 1.1 kardel isneg = 0; 2336 1.1 kardel val = (u_long)pcmd->argval[0].ival; 2337 1.1 kardel } 2338 1.1 kardel 2339 1.1 kardel delay_time.l_ui = val / 1000; 2340 1.1 kardel val %= 1000; 2341 1.1 kardel delay_time.l_uf = val * 4294967; /* 2**32/1000 */ 2342 1.1 kardel 2343 1.1 kardel if (isneg) 2344 1.1 kardel L_NEG(&delay_time); 2345 1.1 kardel } 2346 1.1 kardel } 2347 1.1 kardel 2348 1.1 kardel 2349 1.1 kardel /* 2350 1.1 kardel * host - set the host we are dealing with. 2351 1.1 kardel */ 2352 1.1 kardel static void 2353 1.1 kardel host( 2354 1.1 kardel struct parse *pcmd, 2355 1.1 kardel FILE *fp 2356 1.1 kardel ) 2357 1.1 kardel { 2358 1.1 kardel int i; 2359 1.1 kardel 2360 1.1 kardel if (pcmd->nargs == 0) { 2361 1.1 kardel if (havehost) 2362 1.1 kardel (void) fprintf(fp, "current host is %s\n", 2363 1.1 kardel currenthost); 2364 1.1 kardel else 2365 1.1 kardel (void) fprintf(fp, "no current host\n"); 2366 1.1 kardel return; 2367 1.1 kardel } 2368 1.1 kardel 2369 1.1 kardel i = 0; 2370 1.1 kardel ai_fam_templ = ai_fam_default; 2371 1.1 kardel if (pcmd->nargs == 2) { 2372 1.1 kardel if (!strcmp("-4", pcmd->argval[i].string)) 2373 1.1 kardel ai_fam_templ = AF_INET; 2374 1.1 kardel else if (!strcmp("-6", pcmd->argval[i].string)) 2375 1.1 kardel ai_fam_templ = AF_INET6; 2376 1.1.1.3 christos else 2377 1.1.1.3 christos goto no_change; 2378 1.1 kardel i = 1; 2379 1.1 kardel } 2380 1.1.1.3 christos if (openhost(pcmd->argval[i].string, ai_fam_templ)) { 2381 1.1.1.3 christos fprintf(fp, "current host set to %s\n", currenthost); 2382 1.1 kardel } else { 2383 1.1.1.3 christos no_change: 2384 1.1 kardel if (havehost) 2385 1.1.1.3 christos fprintf(fp, "current host remains %s\n", 2386 1.1.1.3 christos currenthost); 2387 1.1 kardel else 2388 1.1.1.3 christos fprintf(fp, "still no current host\n"); 2389 1.1 kardel } 2390 1.1 kardel } 2391 1.1 kardel 2392 1.1 kardel 2393 1.1 kardel /* 2394 1.1 kardel * poll - do one (or more) polls of the host via NTP 2395 1.1 kardel */ 2396 1.1 kardel /*ARGSUSED*/ 2397 1.1 kardel static void 2398 1.1 kardel ntp_poll( 2399 1.1 kardel struct parse *pcmd, 2400 1.1 kardel FILE *fp 2401 1.1 kardel ) 2402 1.1 kardel { 2403 1.1 kardel (void) fprintf(fp, "poll not implemented yet\n"); 2404 1.1 kardel } 2405 1.1 kardel 2406 1.1 kardel 2407 1.1 kardel /* 2408 1.1 kardel * keyid - get a keyid to use for authenticating requests 2409 1.1 kardel */ 2410 1.1 kardel static void 2411 1.1 kardel keyid( 2412 1.1 kardel struct parse *pcmd, 2413 1.1 kardel FILE *fp 2414 1.1 kardel ) 2415 1.1 kardel { 2416 1.1 kardel if (pcmd->nargs == 0) { 2417 1.1 kardel if (info_auth_keyid == 0) 2418 1.1 kardel (void) fprintf(fp, "no keyid defined\n"); 2419 1.1 kardel else 2420 1.1 kardel (void) fprintf(fp, "keyid is %lu\n", (u_long)info_auth_keyid); 2421 1.1 kardel } else { 2422 1.1 kardel /* allow zero so that keyid can be cleared. */ 2423 1.1 kardel if(pcmd->argval[0].uval > NTP_MAXKEY) 2424 1.1 kardel (void) fprintf(fp, "Invalid key identifier\n"); 2425 1.1 kardel info_auth_keyid = pcmd->argval[0].uval; 2426 1.1 kardel } 2427 1.1 kardel } 2428 1.1 kardel 2429 1.1 kardel /* 2430 1.1 kardel * keytype - get type of key to use for authenticating requests 2431 1.1 kardel */ 2432 1.1 kardel static void 2433 1.1 kardel keytype( 2434 1.1 kardel struct parse *pcmd, 2435 1.1 kardel FILE *fp 2436 1.1 kardel ) 2437 1.1 kardel { 2438 1.1 kardel const char * digest_name; 2439 1.1 kardel size_t digest_len; 2440 1.1 kardel int key_type; 2441 1.1 kardel 2442 1.1 kardel if (!pcmd->nargs) { 2443 1.1.1.2 kardel fprintf(fp, "keytype is %s with %lu octet digests\n", 2444 1.1 kardel keytype_name(info_auth_keytype), 2445 1.1.1.2 kardel (u_long)info_auth_hashlen); 2446 1.1 kardel return; 2447 1.1 kardel } 2448 1.1 kardel 2449 1.1 kardel digest_name = pcmd->argval[0].string; 2450 1.1 kardel digest_len = 0; 2451 1.1 kardel key_type = keytype_from_text(digest_name, &digest_len); 2452 1.1 kardel 2453 1.1 kardel if (!key_type) { 2454 1.1.1.6 christos fprintf(fp, "keytype is not valid. " 2455 1.1 kardel #ifdef OPENSSL 2456 1.1.1.6 christos "Type \"help keytype\" for the available digest types.\n"); 2457 1.1 kardel #else 2458 1.1.1.6 christos "Only \"md5\" is available.\n"); 2459 1.1 kardel #endif 2460 1.1 kardel return; 2461 1.1 kardel } 2462 1.1 kardel 2463 1.1 kardel info_auth_keytype = key_type; 2464 1.1 kardel info_auth_hashlen = digest_len; 2465 1.1 kardel } 2466 1.1 kardel 2467 1.1 kardel 2468 1.1 kardel /* 2469 1.1 kardel * passwd - get an authentication key 2470 1.1 kardel */ 2471 1.1 kardel /*ARGSUSED*/ 2472 1.1 kardel static void 2473 1.1 kardel passwd( 2474 1.1 kardel struct parse *pcmd, 2475 1.1 kardel FILE *fp 2476 1.1 kardel ) 2477 1.1 kardel { 2478 1.1.1.3 christos const char *pass; 2479 1.1 kardel 2480 1.1 kardel if (info_auth_keyid == 0) { 2481 1.1.1.3 christos info_auth_keyid = getkeyid("Keyid: "); 2482 1.1.1.3 christos if (info_auth_keyid == 0) { 2483 1.1.1.3 christos (void)fprintf(fp, "Keyid must be defined\n"); 2484 1.1 kardel return; 2485 1.1 kardel } 2486 1.1 kardel } 2487 1.1.1.2 kardel if (pcmd->nargs >= 1) 2488 1.1.1.2 kardel pass = pcmd->argval[0].string; 2489 1.1 kardel else { 2490 1.1.1.2 kardel pass = getpass_keytype(info_auth_keytype); 2491 1.1.1.2 kardel if ('\0' == pass[0]) { 2492 1.1.1.2 kardel fprintf(fp, "Password unchanged\n"); 2493 1.1.1.2 kardel return; 2494 1.1.1.2 kardel } 2495 1.1 kardel } 2496 1.1.1.3 christos authusekey(info_auth_keyid, info_auth_keytype, 2497 1.1.1.3 christos (const u_char *)pass); 2498 1.1.1.2 kardel authtrust(info_auth_keyid, 1); 2499 1.1 kardel } 2500 1.1 kardel 2501 1.1 kardel 2502 1.1 kardel /* 2503 1.1 kardel * hostnames - set the showhostnames flag 2504 1.1 kardel */ 2505 1.1 kardel static void 2506 1.1 kardel hostnames( 2507 1.1 kardel struct parse *pcmd, 2508 1.1 kardel FILE *fp 2509 1.1 kardel ) 2510 1.1 kardel { 2511 1.1 kardel if (pcmd->nargs == 0) { 2512 1.1 kardel if (showhostnames) 2513 1.1 kardel (void) fprintf(fp, "hostnames being shown\n"); 2514 1.1 kardel else 2515 1.1 kardel (void) fprintf(fp, "hostnames not being shown\n"); 2516 1.1 kardel } else { 2517 1.1 kardel if (STREQ(pcmd->argval[0].string, "yes")) 2518 1.1 kardel showhostnames = 1; 2519 1.1 kardel else if (STREQ(pcmd->argval[0].string, "no")) 2520 1.1 kardel showhostnames = 0; 2521 1.1 kardel else 2522 1.1 kardel (void)fprintf(stderr, "What?\n"); 2523 1.1 kardel } 2524 1.1 kardel } 2525 1.1 kardel 2526 1.1 kardel 2527 1.1 kardel 2528 1.1 kardel /* 2529 1.1 kardel * setdebug - set/change debugging level 2530 1.1 kardel */ 2531 1.1 kardel static void 2532 1.1 kardel setdebug( 2533 1.1 kardel struct parse *pcmd, 2534 1.1 kardel FILE *fp 2535 1.1 kardel ) 2536 1.1 kardel { 2537 1.1 kardel if (pcmd->nargs == 0) { 2538 1.1 kardel (void) fprintf(fp, "debug level is %d\n", debug); 2539 1.1 kardel return; 2540 1.1 kardel } else if (STREQ(pcmd->argval[0].string, "no")) { 2541 1.1 kardel debug = 0; 2542 1.1 kardel } else if (STREQ(pcmd->argval[0].string, "more")) { 2543 1.1 kardel debug++; 2544 1.1 kardel } else if (STREQ(pcmd->argval[0].string, "less")) { 2545 1.1 kardel debug--; 2546 1.1 kardel } else { 2547 1.1 kardel (void) fprintf(fp, "What?\n"); 2548 1.1 kardel return; 2549 1.1 kardel } 2550 1.1 kardel (void) fprintf(fp, "debug level set to %d\n", debug); 2551 1.1 kardel } 2552 1.1 kardel 2553 1.1 kardel 2554 1.1 kardel /* 2555 1.1 kardel * quit - stop this nonsense 2556 1.1 kardel */ 2557 1.1 kardel /*ARGSUSED*/ 2558 1.1 kardel static void 2559 1.1 kardel quit( 2560 1.1 kardel struct parse *pcmd, 2561 1.1 kardel FILE *fp 2562 1.1 kardel ) 2563 1.1 kardel { 2564 1.1 kardel if (havehost) 2565 1.1 kardel closesocket(sockfd); /* cleanliness next to godliness */ 2566 1.1 kardel exit(0); 2567 1.1 kardel } 2568 1.1 kardel 2569 1.1 kardel 2570 1.1 kardel /* 2571 1.1 kardel * version - print the current version number 2572 1.1 kardel */ 2573 1.1 kardel /*ARGSUSED*/ 2574 1.1 kardel static void 2575 1.1 kardel version( 2576 1.1 kardel struct parse *pcmd, 2577 1.1 kardel FILE *fp 2578 1.1 kardel ) 2579 1.1 kardel { 2580 1.1 kardel 2581 1.1 kardel (void) fprintf(fp, "%s\n", Version); 2582 1.1 kardel return; 2583 1.1 kardel } 2584 1.1 kardel 2585 1.1 kardel 2586 1.1 kardel /* 2587 1.1 kardel * raw - set raw mode output 2588 1.1 kardel */ 2589 1.1 kardel /*ARGSUSED*/ 2590 1.1 kardel static void 2591 1.1 kardel raw( 2592 1.1 kardel struct parse *pcmd, 2593 1.1 kardel FILE *fp 2594 1.1 kardel ) 2595 1.1 kardel { 2596 1.1 kardel rawmode = 1; 2597 1.1 kardel (void) fprintf(fp, "Output set to raw\n"); 2598 1.1 kardel } 2599 1.1 kardel 2600 1.1 kardel 2601 1.1 kardel /* 2602 1.1 kardel * cooked - set cooked mode output 2603 1.1 kardel */ 2604 1.1 kardel /*ARGSUSED*/ 2605 1.1 kardel static void 2606 1.1 kardel cooked( 2607 1.1 kardel struct parse *pcmd, 2608 1.1 kardel FILE *fp 2609 1.1 kardel ) 2610 1.1 kardel { 2611 1.1 kardel rawmode = 0; 2612 1.1 kardel (void) fprintf(fp, "Output set to cooked\n"); 2613 1.1 kardel return; 2614 1.1 kardel } 2615 1.1 kardel 2616 1.1 kardel 2617 1.1 kardel /* 2618 1.1 kardel * authenticate - always authenticate requests to this host 2619 1.1 kardel */ 2620 1.1 kardel static void 2621 1.1 kardel authenticate( 2622 1.1 kardel struct parse *pcmd, 2623 1.1 kardel FILE *fp 2624 1.1 kardel ) 2625 1.1 kardel { 2626 1.1 kardel if (pcmd->nargs == 0) { 2627 1.1 kardel if (always_auth) { 2628 1.1 kardel (void) fprintf(fp, 2629 1.1 kardel "authenticated requests being sent\n"); 2630 1.1 kardel } else 2631 1.1 kardel (void) fprintf(fp, 2632 1.1 kardel "unauthenticated requests being sent\n"); 2633 1.1 kardel } else { 2634 1.1 kardel if (STREQ(pcmd->argval[0].string, "yes")) { 2635 1.1 kardel always_auth = 1; 2636 1.1 kardel } else if (STREQ(pcmd->argval[0].string, "no")) { 2637 1.1 kardel always_auth = 0; 2638 1.1 kardel } else 2639 1.1 kardel (void)fprintf(stderr, "What?\n"); 2640 1.1 kardel } 2641 1.1 kardel } 2642 1.1 kardel 2643 1.1 kardel 2644 1.1 kardel /* 2645 1.1 kardel * ntpversion - choose the NTP version to use 2646 1.1 kardel */ 2647 1.1 kardel static void 2648 1.1 kardel ntpversion( 2649 1.1 kardel struct parse *pcmd, 2650 1.1 kardel FILE *fp 2651 1.1 kardel ) 2652 1.1 kardel { 2653 1.1 kardel if (pcmd->nargs == 0) { 2654 1.1 kardel (void) fprintf(fp, 2655 1.1 kardel "NTP version being claimed is %d\n", pktversion); 2656 1.1 kardel } else { 2657 1.1 kardel if (pcmd->argval[0].uval < NTP_OLDVERSION 2658 1.1 kardel || pcmd->argval[0].uval > NTP_VERSION) { 2659 1.1 kardel (void) fprintf(stderr, "versions %d to %d, please\n", 2660 1.1 kardel NTP_OLDVERSION, NTP_VERSION); 2661 1.1 kardel } else { 2662 1.1 kardel pktversion = (u_char) pcmd->argval[0].uval; 2663 1.1 kardel } 2664 1.1 kardel } 2665 1.1 kardel } 2666 1.1 kardel 2667 1.1 kardel 2668 1.1.1.5 christos static void __attribute__((__format__(__printf__, 1, 0))) 2669 1.1.1.5 christos vwarning(const char *fmt, va_list ap) 2670 1.1.1.5 christos { 2671 1.1.1.5 christos int serrno = errno; 2672 1.1.1.5 christos (void) fprintf(stderr, "%s: ", progname); 2673 1.1.1.5 christos vfprintf(stderr, fmt, ap); 2674 1.1.1.9 christos (void) fprintf(stderr, ": %s\n", strerror(serrno)); 2675 1.1.1.5 christos } 2676 1.1.1.5 christos 2677 1.1 kardel /* 2678 1.1 kardel * warning - print a warning message 2679 1.1 kardel */ 2680 1.1.1.5 christos static void __attribute__((__format__(__printf__, 1, 2))) 2681 1.1 kardel warning( 2682 1.1 kardel const char *fmt, 2683 1.1.1.5 christos ... 2684 1.1 kardel ) 2685 1.1 kardel { 2686 1.1.1.5 christos va_list ap; 2687 1.1.1.5 christos va_start(ap, fmt); 2688 1.1.1.5 christos vwarning(fmt, ap); 2689 1.1.1.5 christos va_end(ap); 2690 1.1 kardel } 2691 1.1 kardel 2692 1.1 kardel 2693 1.1 kardel /* 2694 1.1 kardel * error - print a message and exit 2695 1.1 kardel */ 2696 1.1.1.5 christos static void __attribute__((__format__(__printf__, 1, 2))) 2697 1.1 kardel error( 2698 1.1 kardel const char *fmt, 2699 1.1.1.5 christos ... 2700 1.1 kardel ) 2701 1.1 kardel { 2702 1.1.1.5 christos va_list ap; 2703 1.1.1.5 christos va_start(ap, fmt); 2704 1.1.1.5 christos vwarning(fmt, ap); 2705 1.1.1.5 christos va_end(ap); 2706 1.1 kardel exit(1); 2707 1.1 kardel } 2708 1.1 kardel /* 2709 1.1 kardel * getkeyid - prompt the user for a keyid to use 2710 1.1 kardel */ 2711 1.1 kardel static u_long 2712 1.1 kardel getkeyid( 2713 1.1 kardel const char *keyprompt 2714 1.1 kardel ) 2715 1.1 kardel { 2716 1.1.1.2 kardel int c; 2717 1.1 kardel FILE *fi; 2718 1.1 kardel char pbuf[20]; 2719 1.1.1.2 kardel size_t i; 2720 1.1.1.2 kardel size_t ilim; 2721 1.1 kardel 2722 1.1 kardel #ifndef SYS_WINNT 2723 1.1 kardel if ((fi = fdopen(open("/dev/tty", 2), "r")) == NULL) 2724 1.1 kardel #else 2725 1.1 kardel if ((fi = _fdopen(open("CONIN$", _O_TEXT), "r")) == NULL) 2726 1.1 kardel #endif /* SYS_WINNT */ 2727 1.1 kardel fi = stdin; 2728 1.1.1.2 kardel else 2729 1.1 kardel setbuf(fi, (char *)NULL); 2730 1.1 kardel fprintf(stderr, "%s", keyprompt); fflush(stderr); 2731 1.1.1.2 kardel for (i = 0, ilim = COUNTOF(pbuf) - 1; 2732 1.1.1.2 kardel i < ilim && (c = getc(fi)) != '\n' && c != EOF; 2733 1.1.1.2 kardel ) 2734 1.1.1.2 kardel pbuf[i++] = (char)c; 2735 1.1.1.2 kardel pbuf[i] = '\0'; 2736 1.1 kardel if (fi != stdin) 2737 1.1.1.2 kardel fclose(fi); 2738 1.1 kardel 2739 1.1 kardel return (u_long) atoi(pbuf); 2740 1.1 kardel } 2741 1.1 kardel 2742 1.1 kardel 2743 1.1 kardel /* 2744 1.1 kardel * atoascii - printable-ize possibly ascii data using the character 2745 1.1 kardel * transformations cat -v uses. 2746 1.1 kardel */ 2747 1.1 kardel static void 2748 1.1 kardel atoascii( 2749 1.1 kardel const char *in, 2750 1.1 kardel size_t in_octets, 2751 1.1 kardel char *out, 2752 1.1 kardel size_t out_octets 2753 1.1 kardel ) 2754 1.1 kardel { 2755 1.1.1.3 christos const u_char * pchIn; 2756 1.1.1.3 christos const u_char * pchInLimit; 2757 1.1.1.3 christos u_char * pchOut; 2758 1.1.1.3 christos u_char c; 2759 1.1 kardel 2760 1.1 kardel pchIn = (const u_char *)in; 2761 1.1 kardel pchInLimit = pchIn + in_octets; 2762 1.1 kardel pchOut = (u_char *)out; 2763 1.1 kardel 2764 1.1 kardel if (NULL == pchIn) { 2765 1.1 kardel if (0 < out_octets) 2766 1.1 kardel *pchOut = '\0'; 2767 1.1 kardel return; 2768 1.1 kardel } 2769 1.1 kardel 2770 1.1 kardel #define ONEOUT(c) \ 2771 1.1 kardel do { \ 2772 1.1 kardel if (0 == --out_octets) { \ 2773 1.1 kardel *pchOut = '\0'; \ 2774 1.1 kardel return; \ 2775 1.1 kardel } \ 2776 1.1 kardel *pchOut++ = (c); \ 2777 1.1 kardel } while (0) 2778 1.1 kardel 2779 1.1 kardel for ( ; pchIn < pchInLimit; pchIn++) { 2780 1.1 kardel c = *pchIn; 2781 1.1 kardel if ('\0' == c) 2782 1.1 kardel break; 2783 1.1 kardel if (c & 0x80) { 2784 1.1 kardel ONEOUT('M'); 2785 1.1 kardel ONEOUT('-'); 2786 1.1 kardel c &= 0x7f; 2787 1.1 kardel } 2788 1.1 kardel if (c < ' ') { 2789 1.1 kardel ONEOUT('^'); 2790 1.1 kardel ONEOUT((u_char)(c + '@')); 2791 1.1 kardel } else if (0x7f == c) { 2792 1.1 kardel ONEOUT('^'); 2793 1.1 kardel ONEOUT('?'); 2794 1.1 kardel } else 2795 1.1 kardel ONEOUT(c); 2796 1.1 kardel } 2797 1.1 kardel ONEOUT('\0'); 2798 1.1 kardel 2799 1.1 kardel #undef ONEOUT 2800 1.1 kardel } 2801 1.1 kardel 2802 1.1 kardel 2803 1.1 kardel /* 2804 1.1 kardel * makeascii - print possibly ascii data using the character 2805 1.1 kardel * transformations that cat -v uses. 2806 1.1 kardel */ 2807 1.1.1.2 kardel void 2808 1.1 kardel makeascii( 2809 1.1.1.9 christos size_t length, 2810 1.1.1.2 kardel const char *data, 2811 1.1 kardel FILE *fp 2812 1.1 kardel ) 2813 1.1 kardel { 2814 1.1.1.2 kardel const u_char *data_u_char; 2815 1.1.1.2 kardel const u_char *cp; 2816 1.1.1.2 kardel int c; 2817 1.1.1.2 kardel 2818 1.1.1.2 kardel data_u_char = (const u_char *)data; 2819 1.1 kardel 2820 1.1.1.2 kardel for (cp = data_u_char; cp < data_u_char + length; cp++) { 2821 1.1 kardel c = (int)*cp; 2822 1.1 kardel if (c & 0x80) { 2823 1.1 kardel putc('M', fp); 2824 1.1 kardel putc('-', fp); 2825 1.1 kardel c &= 0x7f; 2826 1.1 kardel } 2827 1.1 kardel 2828 1.1 kardel if (c < ' ') { 2829 1.1 kardel putc('^', fp); 2830 1.1 kardel putc(c + '@', fp); 2831 1.1 kardel } else if (0x7f == c) { 2832 1.1 kardel putc('^', fp); 2833 1.1 kardel putc('?', fp); 2834 1.1 kardel } else 2835 1.1 kardel putc(c, fp); 2836 1.1 kardel } 2837 1.1 kardel } 2838 1.1 kardel 2839 1.1 kardel 2840 1.1 kardel /* 2841 1.1 kardel * asciize - same thing as makeascii except add a newline 2842 1.1 kardel */ 2843 1.1 kardel void 2844 1.1 kardel asciize( 2845 1.1 kardel int length, 2846 1.1 kardel char *data, 2847 1.1 kardel FILE *fp 2848 1.1 kardel ) 2849 1.1 kardel { 2850 1.1 kardel makeascii(length, data, fp); 2851 1.1 kardel putc('\n', fp); 2852 1.1 kardel } 2853 1.1 kardel 2854 1.1 kardel 2855 1.1 kardel /* 2856 1.1.1.2 kardel * truncate string to fit clipping excess at end. 2857 1.1.1.2 kardel * "too long" -> "too l" 2858 1.1.1.2 kardel * Used for hostnames. 2859 1.1.1.2 kardel */ 2860 1.1.1.3 christos const char * 2861 1.1.1.2 kardel trunc_right( 2862 1.1.1.2 kardel const char * src, 2863 1.1.1.2 kardel size_t width 2864 1.1.1.2 kardel ) 2865 1.1.1.2 kardel { 2866 1.1.1.2 kardel size_t sl; 2867 1.1.1.2 kardel char * out; 2868 1.1.1.2 kardel 2869 1.1.1.3 christos 2870 1.1.1.2 kardel sl = strlen(src); 2871 1.1.1.2 kardel if (sl > width && LIB_BUFLENGTH - 1 > width && width > 0) { 2872 1.1.1.2 kardel LIB_GETBUF(out); 2873 1.1.1.2 kardel memcpy(out, src, width); 2874 1.1.1.2 kardel out[width] = '\0'; 2875 1.1.1.2 kardel 2876 1.1.1.2 kardel return out; 2877 1.1.1.2 kardel } 2878 1.1.1.2 kardel 2879 1.1.1.2 kardel return src; 2880 1.1.1.2 kardel } 2881 1.1.1.2 kardel 2882 1.1.1.2 kardel 2883 1.1.1.2 kardel /* 2884 1.1.1.2 kardel * truncate string to fit by preserving right side and using '_' to hint 2885 1.1.1.2 kardel * "too long" -> "_long" 2886 1.1.1.2 kardel * Used for local IPv6 addresses, where low bits differentiate. 2887 1.1.1.2 kardel */ 2888 1.1.1.3 christos const char * 2889 1.1.1.2 kardel trunc_left( 2890 1.1.1.2 kardel const char * src, 2891 1.1.1.2 kardel size_t width 2892 1.1.1.2 kardel ) 2893 1.1.1.2 kardel { 2894 1.1.1.2 kardel size_t sl; 2895 1.1.1.2 kardel char * out; 2896 1.1.1.2 kardel 2897 1.1.1.2 kardel 2898 1.1.1.2 kardel sl = strlen(src); 2899 1.1.1.2 kardel if (sl > width && LIB_BUFLENGTH - 1 > width && width > 1) { 2900 1.1.1.2 kardel LIB_GETBUF(out); 2901 1.1.1.2 kardel out[0] = '_'; 2902 1.1.1.2 kardel memcpy(&out[1], &src[sl + 1 - width], width); 2903 1.1.1.2 kardel 2904 1.1.1.2 kardel return out; 2905 1.1.1.2 kardel } 2906 1.1.1.2 kardel 2907 1.1.1.2 kardel return src; 2908 1.1.1.2 kardel } 2909 1.1.1.2 kardel 2910 1.1.1.2 kardel 2911 1.1.1.2 kardel /* 2912 1.1 kardel * Some circular buffer space 2913 1.1 kardel */ 2914 1.1 kardel #define CBLEN 80 2915 1.1 kardel #define NUMCB 6 2916 1.1 kardel 2917 1.1 kardel char circ_buf[NUMCB][CBLEN]; 2918 1.1 kardel int nextcb = 0; 2919 1.1 kardel 2920 1.1 kardel /* 2921 1.1 kardel * nextvar - find the next variable in the buffer 2922 1.1 kardel */ 2923 1.1 kardel int 2924 1.1 kardel nextvar( 2925 1.1.1.9 christos size_t *datalen, 2926 1.1.1.2 kardel const char **datap, 2927 1.1 kardel char **vname, 2928 1.1 kardel char **vvalue 2929 1.1 kardel ) 2930 1.1 kardel { 2931 1.1.1.2 kardel const char *cp; 2932 1.1.1.3 christos const char *np; 2933 1.1.1.2 kardel const char *cpend; 2934 1.1.1.3 christos size_t srclen; 2935 1.1.1.3 christos size_t len; 2936 1.1 kardel static char name[MAXVARLEN]; 2937 1.1 kardel static char value[MAXVALLEN]; 2938 1.1 kardel 2939 1.1 kardel cp = *datap; 2940 1.1 kardel cpend = cp + *datalen; 2941 1.1 kardel 2942 1.1 kardel /* 2943 1.1 kardel * Space past commas and white space 2944 1.1 kardel */ 2945 1.1 kardel while (cp < cpend && (*cp == ',' || isspace((int)*cp))) 2946 1.1.1.2 kardel cp++; 2947 1.1.1.3 christos if (cp >= cpend) 2948 1.1.1.2 kardel return 0; 2949 1.1.1.3 christos 2950 1.1 kardel /* 2951 1.1 kardel * Copy name until we hit a ',', an '=', a '\r' or a '\n'. Backspace 2952 1.1 kardel * over any white space and terminate it. 2953 1.1 kardel */ 2954 1.1.1.3 christos srclen = strcspn(cp, ",=\r\n"); 2955 1.1.1.3 christos srclen = min(srclen, (size_t)(cpend - cp)); 2956 1.1.1.3 christos len = srclen; 2957 1.1.1.5 christos while (len > 0 && isspace((unsigned char)cp[len - 1])) 2958 1.1.1.3 christos len--; 2959 1.1.1.3 christos if (len > 0) 2960 1.1.1.3 christos memcpy(name, cp, len); 2961 1.1.1.3 christos name[len] = '\0'; 2962 1.1 kardel *vname = name; 2963 1.1.1.3 christos cp += srclen; 2964 1.1 kardel 2965 1.1 kardel /* 2966 1.1 kardel * Check if we hit the end of the buffer or a ','. If so we are done. 2967 1.1 kardel */ 2968 1.1.1.3 christos if (cp >= cpend || *cp == ',' || *cp == '\r' || *cp == '\n') { 2969 1.1.1.3 christos if (cp < cpend) 2970 1.1.1.3 christos cp++; 2971 1.1 kardel *datap = cp; 2972 1.1.1.9 christos *datalen = size2int_sat(cpend - cp); 2973 1.1.1.3 christos *vvalue = NULL; 2974 1.1 kardel return 1; 2975 1.1 kardel } 2976 1.1 kardel 2977 1.1 kardel /* 2978 1.1 kardel * So far, so good. Copy out the value 2979 1.1 kardel */ 2980 1.1 kardel cp++; /* past '=' */ 2981 1.1.1.5 christos while (cp < cpend && (isspace((unsigned char)*cp) && *cp != '\r' && *cp != '\n')) 2982 1.1.1.3 christos cp++; 2983 1.1.1.3 christos np = cp; 2984 1.1.1.3 christos if ('"' == *np) { 2985 1.1.1.3 christos do { 2986 1.1.1.3 christos np++; 2987 1.1.1.3 christos } while (np < cpend && '"' != *np); 2988 1.1.1.3 christos if (np < cpend && '"' == *np) 2989 1.1.1.3 christos np++; 2990 1.1.1.3 christos } else { 2991 1.1.1.3 christos while (np < cpend && ',' != *np && '\r' != *np) 2992 1.1.1.3 christos np++; 2993 1.1 kardel } 2994 1.1.1.3 christos len = np - cp; 2995 1.1.1.3 christos if (np > cpend || len >= sizeof(value) || 2996 1.1.1.3 christos (np < cpend && ',' != *np && '\r' != *np)) 2997 1.1.1.3 christos return 0; 2998 1.1.1.3 christos memcpy(value, cp, len); 2999 1.1 kardel /* 3000 1.1 kardel * Trim off any trailing whitespace 3001 1.1 kardel */ 3002 1.1.1.5 christos while (len > 0 && isspace((unsigned char)value[len - 1])) 3003 1.1.1.3 christos len--; 3004 1.1.1.3 christos value[len] = '\0'; 3005 1.1 kardel 3006 1.1 kardel /* 3007 1.1 kardel * Return this. All done. 3008 1.1 kardel */ 3009 1.1.1.3 christos if (np < cpend && ',' == *np) 3010 1.1.1.3 christos np++; 3011 1.1.1.3 christos *datap = np; 3012 1.1.1.9 christos *datalen = size2int_sat(cpend - np); 3013 1.1 kardel *vvalue = value; 3014 1.1 kardel return 1; 3015 1.1 kardel } 3016 1.1 kardel 3017 1.1 kardel 3018 1.1.1.3 christos u_short 3019 1.1.1.3 christos varfmt(const char * varname) 3020 1.1.1.3 christos { 3021 1.1.1.3 christos u_int n; 3022 1.1 kardel 3023 1.1.1.3 christos for (n = 0; n < COUNTOF(cookedvars); n++) 3024 1.1.1.3 christos if (!strcmp(varname, cookedvars[n].varname)) 3025 1.1.1.3 christos return cookedvars[n].fmt; 3026 1.1.1.3 christos 3027 1.1.1.3 christos return PADDING; 3028 1.1.1.3 christos } 3029 1.1 kardel 3030 1.1 kardel 3031 1.1 kardel /* 3032 1.1 kardel * printvars - print variables returned in response packet 3033 1.1 kardel */ 3034 1.1 kardel void 3035 1.1 kardel printvars( 3036 1.1.1.9 christos size_t length, 3037 1.1.1.2 kardel const char *data, 3038 1.1 kardel int status, 3039 1.1 kardel int sttype, 3040 1.1 kardel int quiet, 3041 1.1 kardel FILE *fp 3042 1.1 kardel ) 3043 1.1 kardel { 3044 1.1 kardel if (rawmode) 3045 1.1 kardel rawprint(sttype, length, data, status, quiet, fp); 3046 1.1 kardel else 3047 1.1 kardel cookedprint(sttype, length, data, status, quiet, fp); 3048 1.1 kardel } 3049 1.1 kardel 3050 1.1 kardel 3051 1.1 kardel /* 3052 1.1 kardel * rawprint - do a printout of the data in raw mode 3053 1.1 kardel */ 3054 1.1 kardel static void 3055 1.1 kardel rawprint( 3056 1.1 kardel int datatype, 3057 1.1.1.9 christos size_t length, 3058 1.1.1.2 kardel const char *data, 3059 1.1 kardel int status, 3060 1.1 kardel int quiet, 3061 1.1 kardel FILE *fp 3062 1.1 kardel ) 3063 1.1 kardel { 3064 1.1.1.2 kardel const char *cp; 3065 1.1.1.2 kardel const char *cpend; 3066 1.1 kardel 3067 1.1 kardel /* 3068 1.1 kardel * Essentially print the data as is. We reformat unprintables, though. 3069 1.1 kardel */ 3070 1.1 kardel cp = data; 3071 1.1 kardel cpend = data + length; 3072 1.1 kardel 3073 1.1 kardel if (!quiet) 3074 1.1 kardel (void) fprintf(fp, "status=0x%04x,\n", status); 3075 1.1 kardel 3076 1.1 kardel while (cp < cpend) { 3077 1.1 kardel if (*cp == '\r') { 3078 1.1 kardel /* 3079 1.1 kardel * If this is a \r and the next character is a 3080 1.1 kardel * \n, supress this, else pretty print it. Otherwise 3081 1.1 kardel * just output the character. 3082 1.1 kardel */ 3083 1.1 kardel if (cp == (cpend - 1) || *(cp + 1) != '\n') 3084 1.1 kardel makeascii(1, cp, fp); 3085 1.1.1.5 christos } else if (isspace((unsigned char)*cp) || isprint((unsigned char)*cp)) 3086 1.1 kardel putc(*cp, fp); 3087 1.1 kardel else 3088 1.1 kardel makeascii(1, cp, fp); 3089 1.1 kardel cp++; 3090 1.1 kardel } 3091 1.1 kardel } 3092 1.1 kardel 3093 1.1 kardel 3094 1.1 kardel /* 3095 1.1 kardel * Global data used by the cooked output routines 3096 1.1 kardel */ 3097 1.1 kardel int out_chars; /* number of characters output */ 3098 1.1 kardel int out_linecount; /* number of characters output on this line */ 3099 1.1 kardel 3100 1.1 kardel 3101 1.1 kardel /* 3102 1.1 kardel * startoutput - get ready to do cooked output 3103 1.1 kardel */ 3104 1.1 kardel static void 3105 1.1 kardel startoutput(void) 3106 1.1 kardel { 3107 1.1 kardel out_chars = 0; 3108 1.1 kardel out_linecount = 0; 3109 1.1 kardel } 3110 1.1 kardel 3111 1.1 kardel 3112 1.1 kardel /* 3113 1.1 kardel * output - output a variable=value combination 3114 1.1 kardel */ 3115 1.1 kardel static void 3116 1.1 kardel output( 3117 1.1 kardel FILE *fp, 3118 1.1.1.3 christos const char *name, 3119 1.1.1.3 christos const char *value 3120 1.1 kardel ) 3121 1.1 kardel { 3122 1.1.1.9 christos int len; 3123 1.1 kardel 3124 1.1 kardel /* strlen of "name=value" */ 3125 1.1.1.9 christos len = size2int_sat(strlen(name) + 1 + strlen(value)); 3126 1.1 kardel 3127 1.1 kardel if (out_chars != 0) { 3128 1.1 kardel out_chars += 2; 3129 1.1 kardel if ((out_linecount + len + 2) > MAXOUTLINE) { 3130 1.1 kardel fputs(",\n", fp); 3131 1.1 kardel out_linecount = 0; 3132 1.1 kardel } else { 3133 1.1 kardel fputs(", ", fp); 3134 1.1 kardel out_linecount += 2; 3135 1.1 kardel } 3136 1.1 kardel } 3137 1.1 kardel 3138 1.1 kardel fputs(name, fp); 3139 1.1 kardel putc('=', fp); 3140 1.1 kardel fputs(value, fp); 3141 1.1 kardel out_chars += len; 3142 1.1 kardel out_linecount += len; 3143 1.1 kardel } 3144 1.1 kardel 3145 1.1 kardel 3146 1.1 kardel /* 3147 1.1 kardel * endoutput - terminate a block of cooked output 3148 1.1 kardel */ 3149 1.1 kardel static void 3150 1.1 kardel endoutput( 3151 1.1 kardel FILE *fp 3152 1.1 kardel ) 3153 1.1 kardel { 3154 1.1 kardel if (out_chars != 0) 3155 1.1 kardel putc('\n', fp); 3156 1.1 kardel } 3157 1.1 kardel 3158 1.1 kardel 3159 1.1 kardel /* 3160 1.1 kardel * outputarr - output an array of values 3161 1.1 kardel */ 3162 1.1 kardel static void 3163 1.1 kardel outputarr( 3164 1.1 kardel FILE *fp, 3165 1.1 kardel char *name, 3166 1.1 kardel int narr, 3167 1.1 kardel l_fp *lfp 3168 1.1 kardel ) 3169 1.1 kardel { 3170 1.1.1.9 christos char *bp; 3171 1.1.1.9 christos char *cp; 3172 1.1.1.9 christos size_t i; 3173 1.1.1.9 christos size_t len; 3174 1.1 kardel char buf[256]; 3175 1.1 kardel 3176 1.1 kardel bp = buf; 3177 1.1 kardel /* 3178 1.1 kardel * Hack to align delay and offset values 3179 1.1 kardel */ 3180 1.1 kardel for (i = (int)strlen(name); i < 11; i++) 3181 1.1 kardel *bp++ = ' '; 3182 1.1.1.3 christos 3183 1.1 kardel for (i = narr; i > 0; i--) { 3184 1.1 kardel if (i != narr) 3185 1.1 kardel *bp++ = ' '; 3186 1.1 kardel cp = lfptoms(lfp, 2); 3187 1.1 kardel len = strlen(cp); 3188 1.1 kardel if (len > 7) { 3189 1.1 kardel cp[7] = '\0'; 3190 1.1 kardel len = 7; 3191 1.1 kardel } 3192 1.1 kardel while (len < 7) { 3193 1.1 kardel *bp++ = ' '; 3194 1.1 kardel len++; 3195 1.1 kardel } 3196 1.1 kardel while (*cp != '\0') 3197 1.1 kardel *bp++ = *cp++; 3198 1.1 kardel lfp++; 3199 1.1 kardel } 3200 1.1 kardel *bp = '\0'; 3201 1.1 kardel output(fp, name, buf); 3202 1.1 kardel } 3203 1.1 kardel 3204 1.1 kardel static char * 3205 1.1 kardel tstflags( 3206 1.1 kardel u_long val 3207 1.1 kardel ) 3208 1.1 kardel { 3209 1.1.1.2 kardel register char *cp, *s; 3210 1.1.1.2 kardel size_t cb; 3211 1.1 kardel register int i; 3212 1.1 kardel register const char *sep; 3213 1.1 kardel 3214 1.1 kardel sep = ""; 3215 1.1.1.2 kardel s = cp = circ_buf[nextcb]; 3216 1.1 kardel if (++nextcb >= NUMCB) 3217 1.1.1.2 kardel nextcb = 0; 3218 1.1.1.2 kardel cb = sizeof(circ_buf[0]); 3219 1.1 kardel 3220 1.1.1.2 kardel snprintf(cp, cb, "%02lx", val); 3221 1.1.1.2 kardel cp += strlen(cp); 3222 1.1.1.2 kardel cb -= strlen(cp); 3223 1.1 kardel if (!val) { 3224 1.1.1.3 christos strlcat(cp, " ok", cb); 3225 1.1.1.2 kardel cp += strlen(cp); 3226 1.1.1.2 kardel cb -= strlen(cp); 3227 1.1 kardel } else { 3228 1.1.1.2 kardel if (cb) { 3229 1.1.1.2 kardel *cp++ = ' '; 3230 1.1.1.2 kardel cb--; 3231 1.1.1.2 kardel } 3232 1.1.1.5 christos for (i = 0; i < (int)COUNTOF(tstflagnames); i++) { 3233 1.1 kardel if (val & 0x1) { 3234 1.1.1.2 kardel snprintf(cp, cb, "%s%s", sep, 3235 1.1.1.2 kardel tstflagnames[i]); 3236 1.1 kardel sep = ", "; 3237 1.1.1.2 kardel cp += strlen(cp); 3238 1.1.1.2 kardel cb -= strlen(cp); 3239 1.1 kardel } 3240 1.1 kardel val >>= 1; 3241 1.1 kardel } 3242 1.1 kardel } 3243 1.1.1.2 kardel if (cb) 3244 1.1.1.2 kardel *cp = '\0'; 3245 1.1.1.2 kardel 3246 1.1 kardel return s; 3247 1.1 kardel } 3248 1.1 kardel 3249 1.1 kardel /* 3250 1.1 kardel * cookedprint - output variables in cooked mode 3251 1.1 kardel */ 3252 1.1 kardel static void 3253 1.1 kardel cookedprint( 3254 1.1 kardel int datatype, 3255 1.1.1.9 christos size_t length, 3256 1.1.1.2 kardel const char *data, 3257 1.1 kardel int status, 3258 1.1 kardel int quiet, 3259 1.1 kardel FILE *fp 3260 1.1 kardel ) 3261 1.1 kardel { 3262 1.1 kardel char *name; 3263 1.1 kardel char *value; 3264 1.1 kardel char output_raw; 3265 1.1 kardel int fmt; 3266 1.1 kardel l_fp lfp; 3267 1.1 kardel sockaddr_u hval; 3268 1.1 kardel u_long uval; 3269 1.1 kardel int narr; 3270 1.1.1.3 christos size_t len; 3271 1.1.1.3 christos l_fp lfparr[8]; 3272 1.1.1.3 christos char b[12]; 3273 1.1.1.3 christos char bn[2 * MAXVARLEN]; 3274 1.1.1.3 christos char bv[2 * MAXVALLEN]; 3275 1.1 kardel 3276 1.1.1.3 christos UNUSED_ARG(datatype); 3277 1.1 kardel 3278 1.1 kardel if (!quiet) 3279 1.1 kardel fprintf(fp, "status=%04x %s,\n", status, 3280 1.1 kardel statustoa(datatype, status)); 3281 1.1 kardel 3282 1.1 kardel startoutput(); 3283 1.1 kardel while (nextvar(&length, &data, &name, &value)) { 3284 1.1.1.3 christos fmt = varfmt(name); 3285 1.1.1.3 christos output_raw = 0; 3286 1.1.1.3 christos switch (fmt) { 3287 1.1 kardel 3288 1.1.1.3 christos case PADDING: 3289 1.1.1.3 christos output_raw = '*'; 3290 1.1.1.3 christos break; 3291 1.1 kardel 3292 1.1.1.3 christos case TS: 3293 1.1.1.3 christos if (!decodets(value, &lfp)) 3294 1.1.1.3 christos output_raw = '?'; 3295 1.1.1.3 christos else 3296 1.1.1.3 christos output(fp, name, prettydate(&lfp)); 3297 1.1.1.3 christos break; 3298 1.1 kardel 3299 1.1.1.3 christos case HA: /* fallthru */ 3300 1.1.1.3 christos case NA: 3301 1.1.1.3 christos if (!decodenetnum(value, &hval)) { 3302 1.1.1.3 christos output_raw = '?'; 3303 1.1.1.3 christos } else if (fmt == HA){ 3304 1.1.1.3 christos output(fp, name, nntohost(&hval)); 3305 1.1.1.3 christos } else { 3306 1.1.1.3 christos output(fp, name, stoa(&hval)); 3307 1.1.1.3 christos } 3308 1.1.1.3 christos break; 3309 1.1 kardel 3310 1.1.1.3 christos case RF: 3311 1.1.1.3 christos if (decodenetnum(value, &hval)) { 3312 1.1.1.3 christos if (ISREFCLOCKADR(&hval)) 3313 1.1.1.3 christos output(fp, name, 3314 1.1.1.3 christos refnumtoa(&hval)); 3315 1.1 kardel else 3316 1.1.1.3 christos output(fp, name, stoa(&hval)); 3317 1.1.1.3 christos } else if (strlen(value) <= 4) { 3318 1.1.1.3 christos output(fp, name, value); 3319 1.1.1.3 christos } else { 3320 1.1.1.3 christos output_raw = '?'; 3321 1.1.1.3 christos } 3322 1.1.1.3 christos break; 3323 1.1 kardel 3324 1.1.1.3 christos case LP: 3325 1.1.1.3 christos if (!decodeuint(value, &uval) || uval > 3) { 3326 1.1.1.3 christos output_raw = '?'; 3327 1.1.1.3 christos } else { 3328 1.1.1.3 christos b[0] = (0x2 & uval) 3329 1.1.1.3 christos ? '1' 3330 1.1.1.3 christos : '0'; 3331 1.1.1.3 christos b[1] = (0x1 & uval) 3332 1.1.1.3 christos ? '1' 3333 1.1.1.3 christos : '0'; 3334 1.1.1.3 christos b[2] = '\0'; 3335 1.1.1.3 christos output(fp, name, b); 3336 1.1.1.3 christos } 3337 1.1.1.3 christos break; 3338 1.1.1.3 christos 3339 1.1.1.3 christos case OC: 3340 1.1.1.3 christos if (!decodeuint(value, &uval)) { 3341 1.1.1.3 christos output_raw = '?'; 3342 1.1.1.3 christos } else { 3343 1.1.1.3 christos snprintf(b, sizeof(b), "%03lo", uval); 3344 1.1.1.3 christos output(fp, name, b); 3345 1.1 kardel } 3346 1.1.1.3 christos break; 3347 1.1.1.3 christos 3348 1.1.1.3 christos case AR: 3349 1.1.1.3 christos if (!decodearr(value, &narr, lfparr)) 3350 1.1.1.3 christos output_raw = '?'; 3351 1.1.1.3 christos else 3352 1.1.1.3 christos outputarr(fp, name, narr, lfparr); 3353 1.1.1.3 christos break; 3354 1.1.1.3 christos 3355 1.1.1.3 christos case FX: 3356 1.1.1.3 christos if (!decodeuint(value, &uval)) 3357 1.1.1.3 christos output_raw = '?'; 3358 1.1.1.3 christos else 3359 1.1.1.3 christos output(fp, name, tstflags(uval)); 3360 1.1.1.3 christos break; 3361 1.1 kardel 3362 1.1.1.3 christos default: 3363 1.1.1.3 christos fprintf(stderr, "Internal error in cookedprint, %s=%s, fmt %d\n", 3364 1.1.1.3 christos name, value, fmt); 3365 1.1.1.3 christos output_raw = '?'; 3366 1.1.1.3 christos break; 3367 1.1 kardel } 3368 1.1 kardel 3369 1.1.1.3 christos if (output_raw != 0) { 3370 1.1.1.8 christos /* TALOS-CAN-0063: avoid buffer overrun */ 3371 1.1 kardel atoascii(name, MAXVARLEN, bn, sizeof(bn)); 3372 1.1 kardel if (output_raw != '*') { 3373 1.1.1.8 christos atoascii(value, MAXVALLEN, 3374 1.1.1.8 christos bv, sizeof(bv) - 1); 3375 1.1 kardel len = strlen(bv); 3376 1.1 kardel bv[len] = output_raw; 3377 1.1 kardel bv[len+1] = '\0'; 3378 1.1.1.8 christos } else { 3379 1.1.1.8 christos atoascii(value, MAXVALLEN, 3380 1.1.1.8 christos bv, sizeof(bv)); 3381 1.1 kardel } 3382 1.1 kardel output(fp, bn, bv); 3383 1.1 kardel } 3384 1.1 kardel } 3385 1.1 kardel endoutput(fp); 3386 1.1 kardel } 3387 1.1 kardel 3388 1.1 kardel 3389 1.1 kardel /* 3390 1.1 kardel * sortassoc - sort associations in the cache into ascending order 3391 1.1 kardel */ 3392 1.1 kardel void 3393 1.1 kardel sortassoc(void) 3394 1.1 kardel { 3395 1.1 kardel if (numassoc > 1) 3396 1.1.1.3 christos qsort(assoc_cache, (size_t)numassoc, 3397 1.1.1.3 christos sizeof(assoc_cache[0]), &assoccmp); 3398 1.1 kardel } 3399 1.1 kardel 3400 1.1 kardel 3401 1.1 kardel /* 3402 1.1 kardel * assoccmp - compare two associations 3403 1.1 kardel */ 3404 1.1 kardel static int 3405 1.1 kardel assoccmp( 3406 1.1 kardel const void *t1, 3407 1.1 kardel const void *t2 3408 1.1 kardel ) 3409 1.1 kardel { 3410 1.1.1.2 kardel const struct association *ass1 = t1; 3411 1.1.1.2 kardel const struct association *ass2 = t2; 3412 1.1 kardel 3413 1.1 kardel if (ass1->assid < ass2->assid) 3414 1.1 kardel return -1; 3415 1.1 kardel if (ass1->assid > ass2->assid) 3416 1.1 kardel return 1; 3417 1.1 kardel return 0; 3418 1.1 kardel } 3419 1.1.1.2 kardel 3420 1.1 kardel 3421 1.1 kardel /* 3422 1.1.1.3 christos * grow_assoc_cache() - enlarge dynamic assoc_cache array 3423 1.1.1.3 christos * 3424 1.1.1.3 christos * The strategy is to add an assumed 4k page size at a time, leaving 3425 1.1.1.3 christos * room for malloc() bookkeeping overhead equivalent to 4 pointers. 3426 1.1.1.3 christos */ 3427 1.1.1.3 christos void 3428 1.1.1.3 christos grow_assoc_cache(void) 3429 1.1.1.3 christos { 3430 1.1.1.3 christos static size_t prior_sz; 3431 1.1.1.3 christos size_t new_sz; 3432 1.1.1.3 christos 3433 1.1.1.3 christos new_sz = prior_sz + 4 * 1024; 3434 1.1.1.3 christos if (0 == prior_sz) { 3435 1.1.1.3 christos new_sz -= 4 * sizeof(void *); 3436 1.1.1.3 christos } 3437 1.1.1.3 christos assoc_cache = erealloc_zero(assoc_cache, new_sz, prior_sz); 3438 1.1.1.3 christos prior_sz = new_sz; 3439 1.1.1.9 christos assoc_cache_slots = (u_int)(new_sz / sizeof(assoc_cache[0])); 3440 1.1.1.3 christos } 3441 1.1.1.3 christos 3442 1.1.1.3 christos 3443 1.1.1.3 christos /* 3444 1.1 kardel * ntpq_custom_opt_handler - autoopts handler for -c and -p 3445 1.1 kardel * 3446 1.1 kardel * By default, autoopts loses the relative order of -c and -p options 3447 1.1 kardel * on the command line. This routine replaces the default handler for 3448 1.1 kardel * those routines and builds a list of commands to execute preserving 3449 1.1 kardel * the order. 3450 1.1 kardel */ 3451 1.1 kardel void 3452 1.1 kardel ntpq_custom_opt_handler( 3453 1.1 kardel tOptions *pOptions, 3454 1.1 kardel tOptDesc *pOptDesc 3455 1.1 kardel ) 3456 1.1 kardel { 3457 1.1 kardel switch (pOptDesc->optValue) { 3458 1.1.1.3 christos 3459 1.1 kardel default: 3460 1.1.1.3 christos fprintf(stderr, 3461 1.1 kardel "ntpq_custom_opt_handler unexpected option '%c' (%d)\n", 3462 1.1 kardel pOptDesc->optValue, pOptDesc->optValue); 3463 1.1.1.3 christos exit(1); 3464 1.1 kardel 3465 1.1 kardel case 'c': 3466 1.1 kardel ADDCMD(pOptDesc->pzLastArg); 3467 1.1 kardel break; 3468 1.1 kardel 3469 1.1 kardel case 'p': 3470 1.1 kardel ADDCMD("peers"); 3471 1.1 kardel break; 3472 1.1 kardel } 3473 1.1 kardel } 3474 1.1.1.6 christos /* 3475 1.1.1.6 christos * Obtain list of digest names 3476 1.1.1.6 christos */ 3477 1.1.1.6 christos 3478 1.1.1.6 christos #ifdef OPENSSL 3479 1.1.1.6 christos # ifdef HAVE_EVP_MD_DO_ALL_SORTED 3480 1.1.1.6 christos struct hstate { 3481 1.1.1.6 christos char *list; 3482 1.1.1.6 christos const char **seen; 3483 1.1.1.6 christos int idx; 3484 1.1.1.6 christos }; 3485 1.1.1.6 christos #define K_PER_LINE 8 3486 1.1.1.6 christos #define K_NL_PFX_STR "\n " 3487 1.1.1.6 christos #define K_DELIM_STR ", " 3488 1.1.1.6 christos static void list_md_fn(const EVP_MD *m, const char *from, const char *to, void *arg ) 3489 1.1.1.6 christos { 3490 1.1.1.6 christos size_t len, n; 3491 1.1.1.6 christos const char *name, *cp, **seen; 3492 1.1.1.6 christos struct hstate *hstate = arg; 3493 1.1.1.6 christos EVP_MD_CTX ctx; 3494 1.1.1.6 christos u_int digest_len; 3495 1.1.1.6 christos u_char digest[EVP_MAX_MD_SIZE]; 3496 1.1.1.6 christos 3497 1.1.1.6 christos if (!m) 3498 1.1.1.6 christos return; /* Ignore aliases */ 3499 1.1.1.6 christos 3500 1.1.1.6 christos name = EVP_MD_name(m); 3501 1.1.1.6 christos 3502 1.1.1.6 christos /* Lowercase names aren't accepted by keytype_from_text in ssl_init.c */ 3503 1.1.1.6 christos 3504 1.1.1.6 christos for( cp = name; *cp; cp++ ) { 3505 1.1.1.6 christos if( islower(*cp) ) 3506 1.1.1.6 christos return; 3507 1.1.1.6 christos } 3508 1.1.1.6 christos len = (cp - name) + 1; 3509 1.1.1.6 christos 3510 1.1.1.6 christos /* There are duplicates. Discard if name has been seen. */ 3511 1.1.1.6 christos 3512 1.1.1.6 christos for (seen = hstate->seen; *seen; seen++) 3513 1.1.1.6 christos if (!strcmp(*seen, name)) 3514 1.1.1.6 christos return; 3515 1.1.1.6 christos n = (seen - hstate->seen) + 2; 3516 1.1.1.8 christos hstate->seen = erealloc(hstate->seen, n * sizeof(*seen)); 3517 1.1.1.6 christos hstate->seen[n-2] = name; 3518 1.1.1.6 christos hstate->seen[n-1] = NULL; 3519 1.1.1.6 christos 3520 1.1.1.6 christos /* Discard MACs that NTP won't accept. 3521 1.1.1.6 christos * Keep this consistent with keytype_from_text() in ssl_init.c. 3522 1.1.1.6 christos */ 3523 1.1.1.6 christos 3524 1.1.1.6 christos EVP_DigestInit(&ctx, EVP_get_digestbyname(name)); 3525 1.1.1.6 christos EVP_DigestFinal(&ctx, digest, &digest_len); 3526 1.1.1.6 christos if (digest_len > (MAX_MAC_LEN - sizeof(keyid_t))) 3527 1.1.1.6 christos return; 3528 1.1.1.6 christos 3529 1.1.1.6 christos if (hstate->list != NULL) 3530 1.1.1.6 christos len += strlen(hstate->list); 3531 1.1.1.6 christos len += (hstate->idx >= K_PER_LINE)? strlen(K_NL_PFX_STR): strlen(K_DELIM_STR); 3532 1.1.1.6 christos 3533 1.1.1.6 christos if (hstate->list == NULL) { 3534 1.1.1.8 christos hstate->list = (char *)emalloc(len); 3535 1.1.1.6 christos hstate->list[0] = '\0'; 3536 1.1.1.6 christos } else 3537 1.1.1.8 christos hstate->list = (char *)erealloc(hstate->list, len); 3538 1.1.1.6 christos 3539 1.1.1.6 christos sprintf(hstate->list + strlen(hstate->list), "%s%s", 3540 1.1.1.6 christos ((hstate->idx >= K_PER_LINE)? K_NL_PFX_STR : K_DELIM_STR), 3541 1.1.1.6 christos name); 3542 1.1.1.6 christos if (hstate->idx >= K_PER_LINE) 3543 1.1.1.6 christos hstate->idx = 1; 3544 1.1.1.6 christos else 3545 1.1.1.6 christos hstate->idx++; 3546 1.1.1.6 christos } 3547 1.1.1.6 christos # endif 3548 1.1.1.6 christos #endif 3549 1.1.1.6 christos 3550 1.1.1.6 christos static char *list_digest_names(void) 3551 1.1.1.6 christos { 3552 1.1.1.6 christos char *list = NULL; 3553 1.1.1.6 christos 3554 1.1.1.6 christos #ifdef OPENSSL 3555 1.1.1.6 christos # ifdef HAVE_EVP_MD_DO_ALL_SORTED 3556 1.1.1.6 christos struct hstate hstate = { NULL, NULL, K_PER_LINE+1 }; 3557 1.1.1.6 christos 3558 1.1.1.8 christos hstate.seen = (const char **) emalloc_zero(1*sizeof( const char * )); // replaces -> calloc(1, sizeof( const char * )); 3559 1.1.1.6 christos 3560 1.1.1.6 christos INIT_SSL(); 3561 1.1.1.6 christos EVP_MD_do_all_sorted(list_md_fn, &hstate); 3562 1.1.1.6 christos list = hstate.list; 3563 1.1.1.6 christos free(hstate.seen); 3564 1.1.1.6 christos # else 3565 1.1.1.8 christos list = (char *)emalloc(sizeof("md5, others (upgrade to OpenSSL-1.0 for full list)")); 3566 1.1.1.6 christos strcpy(list, "md5, others (upgrade to OpenSSL-1.0 for full list)"); 3567 1.1.1.6 christos # endif 3568 1.1.1.6 christos #else 3569 1.1.1.8 christos list = (char *)emalloc(sizeof("md5")); 3570 1.1.1.6 christos strcpy(list, "md5"); 3571 1.1.1.6 christos #endif 3572 1.1.1.6 christos 3573 1.1.1.6 christos return list; 3574 1.1.1.6 christos } 3575 1.1.1.9 christos 3576 1.1.1.9 christos #define CTRLC_STACK_MAX 4 3577 1.1.1.9 christos static volatile size_t ctrlc_stack_len = 0; 3578 1.1.1.9 christos static volatile Ctrl_C_Handler ctrlc_stack[CTRLC_STACK_MAX]; 3579 1.1.1.9 christos 3580 1.1.1.9 christos 3581 1.1.1.9 christos 3582 1.1.1.9 christos int/*BOOL*/ 3583 1.1.1.9 christos push_ctrl_c_handler( 3584 1.1.1.9 christos Ctrl_C_Handler func 3585 1.1.1.9 christos ) 3586 1.1.1.9 christos { 3587 1.1.1.9 christos size_t size = ctrlc_stack_len; 3588 1.1.1.9 christos if (func && (size < CTRLC_STACK_MAX)) { 3589 1.1.1.9 christos ctrlc_stack[size] = func; 3590 1.1.1.9 christos ctrlc_stack_len = size + 1; 3591 1.1.1.9 christos return TRUE; 3592 1.1.1.9 christos } 3593 1.1.1.9 christos return FALSE; 3594 1.1.1.9 christos } 3595 1.1.1.9 christos 3596 1.1.1.9 christos int/*BOOL*/ 3597 1.1.1.9 christos pop_ctrl_c_handler( 3598 1.1.1.9 christos Ctrl_C_Handler func 3599 1.1.1.9 christos ) 3600 1.1.1.9 christos { 3601 1.1.1.9 christos size_t size = ctrlc_stack_len; 3602 1.1.1.9 christos if (size) { 3603 1.1.1.9 christos --size; 3604 1.1.1.9 christos if (func == NULL || func == ctrlc_stack[size]) { 3605 1.1.1.9 christos ctrlc_stack_len = size; 3606 1.1.1.9 christos return TRUE; 3607 1.1.1.9 christos } 3608 1.1.1.9 christos } 3609 1.1.1.9 christos return FALSE; 3610 1.1.1.9 christos } 3611 1.1.1.9 christos 3612 1.1.1.9 christos static void 3613 1.1.1.9 christos on_ctrlc(void) 3614 1.1.1.9 christos { 3615 1.1.1.9 christos size_t size = ctrlc_stack_len; 3616 1.1.1.9 christos while (size) 3617 1.1.1.9 christos if ((*ctrlc_stack[--size])()) 3618 1.1.1.9 christos break; 3619 1.1.1.9 christos } 3620
Indexes created Fri Mar 27 00:22:57 UTC 2026