xref: /freebsd/contrib/ntp/sntp/main.c (revision 39beb93c3f8bdbf72a61fda42300b5ebed7390c8)
1 /*  Copyright (C) 1996, 1997, 2000 N.M. Maclaren
2     Copyright (C) 1996, 1997, 2000 The University of Cambridge
3 
4 This is a complete SNTP implementation, which was easier to write than to port
5 xntp to a new version of Unix with any hope of maintaining it thereafter.  It
6 supports the full SNTP (RFC 2030) client- and server-side challenge-response
7 and broadcast protocols.  It should achieve nearly optimal accuracy with very
8 few transactions, provided only that a client has access to a trusted server
9 and that communications are not INVARIABLY slow.  As this is the environment in
10 which 90-99% of all NTP systems are run ....
11 
12 The specification of this program is:
13 
14     sntp [ --help | -h | -? ] [ -v | -V | -W ]
15         [ -q [ -f savefile ] |
16             [ { -r | -a } [ -P prompt ] [ -l lockfile ] ]
17             [ -c count ] [ -e minerr ][ -E maxerr ]
18             [ -d delay | -x [ separation ] [ -f savefile ] ]
19             [ -4 | -6 ] [ address(es) ] ]
20 
21     --help, -h and -? all print the syntax of the command.
22 
23     -v indicates that diagnostic messages should be written to standard error,
24 and -V requests more output for investigating apparently inconsistent
25 timestamps.  -W requests very verbose debugging output, and will interfere with
26 the timing when writing to the terminal (because of line buffered output from
27 C); it is useful only when debugging the source.  Note that the times produced
28 by -V and -W are the corrections needed, and not the error in the local clock.
29 
30     -q indicates that it will query a savefile that is being maintained by
31 it being run in daemon mode.
32 
33      The default is that it should behave as a client, and the following options
34 are then relevant:
35 
36     -r indicates that the system clock should be reset by 'settimeofday'.
37 Naturally, this will work only if the user has enough privilege.
38 
39     -a indicates that the system clock should be reset by 'adjtime'.
40 Naturally, this will work only if the user has enough privilege.
41 
42     -x indicates that the program should run as a daemon (i.e. forever), and
43 allow for clock drift.
44 
45     -4 or -6 force dns resolving to ipv4 or ipv6 addresses.
46 
47     The default is to write the current date and time to the standard output in
48 a format like '1996 Oct 15 20:17:25.123 + 4.567 +/- 0.089 secs', indicating the
49 estimated true (local) time and the error in the local clock.  In daemon mode,
50 it will add drift information in a format like ' + 1.3 +/- 0.1 ppm', and
51 display this at roughly 'separation' intervals.
52 
53     'minerr' is the maximum ignorable variation between the clocks.  Acceptable
54 values are from 0.001 to 1, and the default is 0.1 if 'address' is specified
55 and 0.5 otherwise.
56 
57     'maxerr' is the maximum value of various delays that are deemed acceptable.
58 Acceptable values are from 1 to 60, and the default is 5.  It should sometimes
59 be increased if there are problems with the network, NTP server or system
60 clock, but take care.
61 
62     'prompt' is the maximum clock change that will be made automatically.
63 Acceptable values are from 1 to 3600, and the default is 30.  If the program is
64 being run interactively, larger values will cause a prompt.  The value may also
65 be 'no', and the change will be made without prompting.
66 
67     'count' is the maximum number of NTP packets to require.  Acceptable values
68 are from 1 to 25 if 'address' is specified and '-x' is not, and from 5 to 25
69 otherwise; the default is 5.  If the maximum isn't enough, you need a better
70 consistency algorithm than this program uses.  Don't increase it.
71 
72     'delay' is a rough limit on the total running time in seconds.  Acceptable
73 values are from 1 to 3600, and the default is 15 if 'address' is specified and
74 300 otherwise.
75 
76     'separation' is the time to wait between calls to the server in minutes if
77 'address' is specified, and the minimum time between broadcast packets if not.
78 Acceptable values are from 1 to 1440 (a day), and the default is 300.
79 
80     'lockfile' may be used in an update mode to ensure that there is only
81 one copy of sntp running at once.  The default is installation-dependent,
82 but will usually be /etc/sntp.pid.
83 
84     'savefile' may be used in daemon mode to store a record of previous
85 packets, which may speed up recalculating the drift after sntp has to be
86 restarted (e.g. because of network or server outages).  The default is
87 installation-dependent, but will usually be /etc/sntp.state.  Note that
88 there is no locking of this file, and using it twice may cause chaos.
89 
90     'address' is the DNS name or IP number of a host to poll; if no name is
91 given, the program waits for broadcasts.  Note that a single component numeric
92 address is not allowed.
93 
94 For sanity, it is also required that 'minerr' < 'maxerr' < 'delay' (if
95 listening for broadcasts, 'delay/count' and, in daemon mode, 'separation') and,
96 for sordid Unixish reasons, that 2*'count' < 'delay'.  The last could be fixed,
97 but isn't worth it.  Note that none of the above values are closely linked to
98 the limits described in the NTP protocol (RFC 1305).  Do not increase the
99 compiled-in bounds excessively, or the code will fail.
100 
101 The algorithm used to decide whether to accept a correction is whether it would
102 seem to improve matters.  Unlike the 'xntp' suite, little attempt is made to
103 handle really knotted scenarios, and diagnostics are written to standard error.
104 In non-daemon client mode, it is intended to be run as a command or in a 'cron'
105 job.  Unlike 'ntpdate', its default mode is simply to display the clock error.
106 
107 It assumes that floating-point arithmetic is tolerably efficient, which is true
108 for even the cheapest personal computer nowadays.  If, however, you want to
109 port this to a toaster, you may have problems!
110 
111 In its terminating modes, its return code is EXIT_SUCCESS if the operation was
112 completed successfully and EXIT_FAILURE otherwise.
113 
114 In daemon mode, it runs for ever and stops with a return code EXIT_FAILURE
115 only after a severe error.  In daemon mode, it will fail if the server is
116 inaccessible for a long time or seriously sick, and will need manual
117 restarting.
118 
119 
120 WARNING: this program has reached its 'hack count' and needs restructuring,
121 badly.  Perhaps the worst code is in run_daemon().  You are advised not to
122 fiddle unless you really have to. */
123 
124 
125 
126 #include "header.h"
127 
128 #include <limits.h>
129 #include <float.h>
130 #include <math.h>
131 
132 #define MAIN
133 #include "kludges.h"
134 #undef MAIN
135 
136 
137 
138 /* NTP definitions.  Note that these assume 8-bit bytes - sigh.  There is
139 little point in parameterising everything, as it is neither feasible nor
140 useful.  It would be very useful if more fields could be defined as
141 unspecified.  The NTP packet-handling routines contain a lot of extra
142 assumptions. */
143 
144 #define JAN_1970   2208988800.0        /* 1970 - 1900 in seconds */
145 #define NTP_SCALE  4294967296.0        /* 2^32, of course! */
146 
147 #define NTP_PACKET_MIN       48        /* Without authentication */
148 #define NTP_PACKET_MAX       68        /* With authentication (ignored) */
149 #define NTP_DISP_FIELD        8        /* Offset of dispersion field */
150 #define NTP_REFERENCE        16        /* Offset of reference timestamp */
151 #define NTP_ORIGINATE        24        /* Offset of originate timestamp */
152 #define NTP_RECEIVE          32        /* Offset of receive timestamp */
153 #define NTP_TRANSMIT         40        /* Offset of transmit timestamp */
154 
155 #define NTP_LI_FUDGE          0        /* The current 'status' */
156 #define NTP_VERSION           3        /* The current version */
157 #define NTP_VERSION_MAX       4        /* The maximum valid version */
158 #define NTP_STRATUM          15        /* The current stratum as a server */
159 #define NTP_STRATUM_MAX      15        /* The maximum valid stratum */
160 #define NTP_POLLING           8        /* The current 'polling interval' */
161 #define NTP_PRECISION         0        /* The current 'precision' - 1 sec. */
162 
163 #define NTP_ACTIVE            1        /* NTP symmetric active request */
164 #define NTP_PASSIVE           2        /* NTP symmetric passive response */
165 #define NTP_CLIENT            3        /* NTP client request */
166 #define NTP_SERVER            4        /* NTP server response */
167 #define NTP_BROADCAST         5        /* NTP server broadcast */
168 
169 #define NTP_INSANITY     3600.0        /* Errors beyond this are hopeless */
170 #define RESET_MIN            15        /* Minimum period between resets */
171 #define ABSCISSA            3.0        /* Scale factor for standard errors */
172 
173 
174 
175 /* Local definitions and global variables (mostly options).  These are all of
176 the quantities that control the main actions of the program.  The first three
177 are the only ones that are exported to other modules. */
178 
179 const char *argv0 = NULL;              /* For diagnostics only - not NULL */
180 int verbose = 0,                       /* Default = 0, -v = 1, -V = 2, -W = 3 */
181     operation = 0;                     /* Defined in header.h - see action */
182 const char *lockname = NULL;           /* The name of the lock file */
183 int unprivport = 0;			/* Use an unpriv port for query? */
184 
185 #define COUNT_MAX          25          /* Do NOT increase this! */
186 #define WEEBLE_FACTOR     1.2          /* See run_server() and run_daemon() */
187 #define ETHERNET_MAX        5          /* See run_daemon() and run_client() */
188 
189 #define action_display      1          /* Just display the result */
190 #define action_reset        2          /* Reset using 'settimeofday' */
191 #define action_adjust       3          /* Reset using 'adjtime' */
192 #define action_broadcast    4          /* Behave as a server, broadcasting */
193 #define action_server       5          /* Behave as a server for clients */
194 #define action_query        6          /* Query a daemon savefile */
195 
196 #define save_read_only      1          /* Read the saved state only */
197 #define save_read_check     2          /* Read and check it */
198 #define save_write          3          /* Write the saved state */
199 #define save_clear          4          /* Clear the saved state */
200 
201 static const char version[] = VERSION; /* For reverse engineering :-) */
202 static int action = 0,                 /* Defined above - see operation */
203     count = 0,                         /* -c value in seconds */
204     delay = 0,                         /* -d or -x value in seconds */
205     attempts = 0,                      /* Packets transmitted up to 2*count */
206     waiting = 0,                       /* -d/-c except for in daemon mode */
207     locked = 0;                        /* set_lock(1) has been called */
208 static double outgoing[2*COUNT_MAX],   /* Transmission timestamps */
209     minerr = 0.0,                      /* -e value in seconds */
210     maxerr = 0.0,                      /* -E value in seconds */
211     prompt = 0.0,                      /* -p value in seconds */
212     dispersion = 0.0;                  /* The source dispersion in seconds */
213 static FILE *savefile = NULL;          /* Holds the data to restart from */
214 
215 
216 
217 /* The unpacked NTP data structure, with all the fields even remotely relevant
218 to SNTP. */
219 
220 typedef struct NTP_DATA {
221     unsigned char status, version, mode, stratum, polling;
222     signed char precision;
223     double dispersion, reference, originate, receive, transmit, current;
224 } ntp_data;
225 
226 
227 
228 /* The following structure is used to keep a record of packets in daemon mode;
229 it contains only the information that is actually used for the drift and error
230 calculations. */
231 
232 typedef struct {
233     double dispersion, weight, when, offset, error;
234 } data_record;
235 
236 void syntax(int);
237 void display_data(ntp_data *);
238 void display_packet(unsigned char *, int);
239 void pack_ntp(unsigned char *, int, ntp_data *);
240 void unpack_ntp(ntp_data *, unsigned char *, int);
241 void make_packet(ntp_data *, int);
242 int read_packet(int, ntp_data *, double *, double *);
243 void format_time(char *, int, double, double, double, double, int);
244 double reset_clock(double, double, int);
245 void run_server(void);
246 double estimate_stats(int *, int *, data_record *, double, double *, double *,
247 	double *, double *, double *, double *, int *, int);
248 double correct_drift(double *, double *, double);
249 void handle_saving(int, int *, int *, int *, data_record *, double *,
250 	double *, double *);
251 void query_savefile(void);
252 void run_daemon(char **, int, int);
253 void run_client(char **, int);
254 
255 void fatal (int syserr, const char *message, const char *insert) {
256 
257 /* Issue a diagnostic and stop.  Be a little paranoid about recursion. */
258 
259     int k = errno;
260     static int called = 0;
261 
262     if (message != NULL) {
263         fprintf(stderr,"%s: ",argv0);
264         fprintf(stderr,message,insert);
265         fprintf(stderr,"\n");
266     }
267     errno = k;
268     if (syserr) perror(argv0);
269     if (! called) {
270         called = 1;
271         if (savefile != NULL && fclose(savefile))
272             fatal(1,"unable to close the daemon save file",NULL);
273         if (locked) set_lock(0);
274     }
275     exit(EXIT_FAILURE);
276 }
277 
278 
279 
280 void syntax (int halt) {
281 
282 /* The standard, unfriendly Unix error message.  Some errors are diagnosed more
283 helpfully.  This is called before any files or sockets are opened. */
284 
285     fprintf(stderr,"Syntax: %s [ --help | -h | -? ] [ -v | -V | -W ] \n",argv0);
286     fprintf(stderr,"    [ -q [ -f savefile ] |\n");
287     fprintf(stderr,"        [ { -r | -a } [ -P prompt ] [ -l lockfile ] ]\n");
288     fprintf(stderr,"            [ -c count ] [ -e minerr ] [ -E maxerr ]\n");
289     fprintf(stderr,"            [ -d delay | -x [ separation ] ");
290     fprintf(stderr,"[ -f savefile ] ]\n");
291     fprintf(stderr,"        [ -4 | -6 ] [-u] [ address(es) ] ]\n");
292     if (halt) exit(EXIT_FAILURE);
293 }
294 
295 
296 
297 void display_data (ntp_data *data) {
298 
299 /* This formats the essential NTP data, as a debugging aid. */
300 
301     fprintf(stderr,"sta=%d ver=%d mod=%d str=%d pol=%d dis=%.6f ref=%.6f\n",
302         data->status,data->version,data->mode,data->stratum,data->polling,
303         data->dispersion,data->reference);
304     fprintf(stderr,"ori=%.6f rec=%.6f\n",data->originate,data->receive);
305     fprintf(stderr,"tra=%.6f cur=%.6f\n",data->transmit,data->current);
306 }
307 
308 
309 
310 void display_packet (unsigned char *packet, int length) {
311 
312 /* This formats a possible packet very roughly, as a debugging aid. */
313 
314     int i;
315 
316     if (length < NTP_PACKET_MIN || length > NTP_PACKET_MAX) return;
317     for (i = 0; i < length; ++i) {
318         if (i != 0 && i%32 == 0)
319             fprintf(stderr,"\n");
320          else if (i != 0 && i%4 == 0)
321              fprintf(stderr," ");
322          fprintf(stderr,"%.2x",packet[i]);
323     }
324     fprintf(stderr,"\n");
325 }
326 
327 
328 
329 void pack_ntp (unsigned char *packet, int length, ntp_data *data) {
330 
331 /* Pack the essential data into an NTP packet, bypassing struct layout and
332 endian problems.  Note that it ignores fields irrelevant to SNTP. */
333 
334     int i, k;
335     double d;
336 
337     memset(packet,0,(size_t)length);
338     packet[0] = (data->status<<6)|(data->version<<3)|data->mode;
339     packet[1] = data->stratum;
340     packet[2] = data->polling;
341     packet[3] = data->precision;
342     d = data->originate/NTP_SCALE;
343     for (i = 0; i < 8; ++i) {
344         if ((k = (int)(d *= 256.0)) >= 256) k = 255;
345         packet[NTP_ORIGINATE+i] = k;
346         d -= k;
347     }
348     d = data->receive/NTP_SCALE;
349     for (i = 0; i < 8; ++i) {
350         if ((k = (int)(d *= 256.0)) >= 256) k = 255;
351         packet[NTP_RECEIVE+i] = k;
352         d -= k;
353     }
354     d = data->transmit/NTP_SCALE;
355     for (i = 0; i < 8; ++i) {
356         if ((k = (int)(d *= 256.0)) >= 256) k = 255;
357         packet[NTP_TRANSMIT+i] = k;
358         d -= k;
359     }
360 }
361 
362 
363 
364 void unpack_ntp (ntp_data *data, unsigned char *packet, int length) {
365 
366 /* Unpack the essential data from an NTP packet, bypassing struct layout and
367 endian problems.  Note that it ignores fields irrelevant to SNTP. */
368 
369     int i;
370     double d;
371 
372     data->current = current_time(JAN_1970);    /* Best to come first */
373     data->status = (packet[0] >> 6);
374     data->version = (packet[0] >> 3)&0x07;
375     data->mode = packet[0]&0x07;
376     data->stratum = packet[1];
377     data->polling = packet[2];
378     data->precision = packet[3];
379     d = 0.0;
380     for (i = 0; i < 4; ++i) d = 256.0*d+packet[NTP_DISP_FIELD+i];
381     data->dispersion = d/65536.0;
382     d = 0.0;
383     for (i = 0; i < 8; ++i) d = 256.0*d+packet[NTP_REFERENCE+i];
384     data->reference = d/NTP_SCALE;
385     d = 0.0;
386     for (i = 0; i < 8; ++i) d = 256.0*d+packet[NTP_ORIGINATE+i];
387     data->originate = d/NTP_SCALE;
388     d = 0.0;
389     for (i = 0; i < 8; ++i) d = 256.0*d+packet[NTP_RECEIVE+i];
390     data->receive = d/NTP_SCALE;
391     d = 0.0;
392     for (i = 0; i < 8; ++i) d = 256.0*d+packet[NTP_TRANSMIT+i];
393     data->transmit = d/NTP_SCALE;
394 }
395 
396 
397 
398 void make_packet (ntp_data *data, int mode) {
399 
400 /* Create an outgoing NTP packet, either from scratch or starting from a
401 request from a client.  Note that it implements the NTP specification, even
402 when this is clearly misguided, except possibly for the setting of LI.  It
403 would be easy enough to add a sanity flag, but I am not in the business of
404 designing an alternative protocol (however much better it might be). */
405 
406     data->status = NTP_LI_FUDGE<<6;
407     data->stratum = NTP_STRATUM;
408     data->reference = data->dispersion = 0.0;
409     if (mode == NTP_SERVER) {
410         data->mode = (data->mode == NTP_CLIENT ? NTP_SERVER : NTP_PASSIVE);
411         data->originate = data->transmit;
412         data->receive = data->current;
413     } else {
414         data->version = NTP_VERSION;
415         data->mode = mode;
416         data->polling = NTP_POLLING;
417         data->precision = NTP_PRECISION;
418         data->receive = data->originate = 0.0;
419     }
420     data->current = data->transmit = current_time(JAN_1970);
421 }
422 
423 
424 
425 int read_packet (int which, ntp_data *data, double *off, double *err) {
426 
427 /* Check the packet and work out the offset and optionally the error.  Note
428 that this contains more checking than xntp does.  This returns 0 for success, 1
429 for failure and 2 for an ignored broadcast packet (a kludge for servers).  Note
430 that it must not change its arguments if it fails. */
431 
432     unsigned char receive[NTP_PACKET_MAX+1];
433     double delay1, delay2, x, y;
434     int response = 0, failed, length, i, k;
435 
436 /* Read the packet and deal with diagnostics. */
437 
438     if ((length = read_socket(which,receive,NTP_PACKET_MAX+1,waiting)) <= 0)
439         return 1;
440     if (length < NTP_PACKET_MIN || length > NTP_PACKET_MAX) {
441         if (verbose)
442             fprintf(stderr,"%s: bad length %d for NTP packet on socket %d\n",
443                 argv0,length,which);
444         return 1;
445     }
446     if (verbose > 2) {
447         fprintf(stderr,"Incoming packet on socket %d:\n",which);
448         display_packet(receive,length);
449     }
450     unpack_ntp(data,receive,length);
451     if (verbose > 2) display_data(data);
452 
453 /* Start by checking that the packet looks reasonable.  Be a little paranoid,
454 but allow for version 1 semantics and sick clients. */
455 
456     if (operation == op_listen)
457         failed = (data->mode != NTP_BROADCAST);
458     else {
459         failed = (data->mode != NTP_SERVER && data->mode != NTP_PASSIVE);
460         response = 1;
461     }
462     if (failed || data->status == 3 || data->version < 1 ||
463             data->version > NTP_VERSION_MAX ||
464             data->stratum > NTP_STRATUM_MAX) {
465         if (verbose)
466             fprintf(stderr,
467                 "%s: Unusable NTP packet rejected on socket %d (f=%d, status %d, version %d, stratum %d)\n",
468                 argv0, which,
469 		failed, data->status, data->version, data->stratum);
470         return 1;
471     }
472 
473 /* Note that the conventions are very poorly defined in the NTP protocol, so we
474 have to guess.  Any full NTP server perpetrating completely unsynchronised
475 packets is an abomination, anyway, so reject it. */
476 
477     delay1 = data->transmit-data->receive;
478     delay2 = data->current-data->originate;
479     failed = (
480 	      (  data->stratum != 0
481 	      /* && data->stratum != NTP_STRATUM_MAX */
482 	      && data->reference == 0.0
483 	      )
484 	     || data->transmit == 0.0
485 	     );
486     if (response &&
487             (data->originate == 0.0 || data->receive == 0.0 ||
488                 (data->reference != 0.0 && data->receive < data->reference) ||
489                 delay1 < 0.0 || delay1 > NTP_INSANITY || delay2 < 0.0 ||
490                 data->dispersion > NTP_INSANITY))
491         failed = 1;
492     if (failed) {
493         if (verbose)
494             fprintf(stderr,
495                 "%s: incomprehensible NTP packet rejected on socket %d\n",
496                 argv0,which);
497         return 1;
498     }
499     if (data->stratum == NTP_STRATUM_MAX) {
500 	fprintf(stderr,
501 	    "%s: unsynch NTP response on socket %d\n",
502 	    argv0,which);
503         return 1;
504     }
505 
506 /* If it is a response, check that it corresponds to one of our requests and
507 has got here in a reasonable length of time. */
508 
509     if (response) {
510         k = 0;
511         for (i = 0; i < attempts; ++i)
512             if (data->originate == outgoing[i]) {
513                 outgoing[i] = 0.0;
514                 ++k;
515             }
516         if (k != 1 || delay2 > NTP_INSANITY) {
517             if (verbose)
518                 fprintf(stderr,
519                     "%s: bad response from NTP server rejected on socket %d\n",
520                     argv0,which);
521             return 1;
522         }
523     }
524 
525 /* Now return the time information.  If it is a server response, it contains
526 enough information that we can be almost certain that we have not been fooled
527 too badly.  Heaven help us with broadcasts - make a wild kludge here, and see
528 elsewhere for other kludges. */
529 
530     if (dispersion < data->dispersion) dispersion = data->dispersion;
531     if (operation == op_listen) {
532         *off = data->transmit-data->current;
533         *err = NTP_INSANITY;
534     } else {
535         x = data->receive-data->originate;
536         y = (data->transmit == 0.0 ? 0.0 : data->transmit-data->current);
537         *off = 0.5*(x+y);
538         *err = x-y;
539         x = data->current-data->originate;
540         if (0.5*x > *err) *err = 0.5*x;
541     }
542     return 0;
543 }
544 
545 
546 
547 void format_time (char *text, int length, double offset, double error,
548     double drift, double drifterr, int precision) {
549 
550 /* Format the current time into a string, with the extra information as
551 requested.  Note that the rest of the program uses the correction needed, which
552 is what is printed for diagnostics, but this formats the error in the local
553 system for display to users.  So the results from this are the negation of
554 those printed by the verbose options. */
555 
556     int milli, len;
557     time_t now;
558     struct tm *gmt;
559     static const char *months[] = {
560         "Jan", "Feb", "Mar", "Apr", "May", "Jun",
561         "Jul", "Aug", "Sep", "Oct", "Nov", "Dec"
562     };
563 
564 /* Work out and format the current local time.  Note that some semi-ANSI
565 systems do not set the return value from (s)printf. */
566 
567     now = convert_time(current_time(offset),&milli);
568     errno = 0;
569     if ((gmt = localtime(&now)) == NULL)
570         fatal(1,"unable to work out local time",NULL);
571     len = 21;
572     if (length <= len) fatal(0,"internal error calling format_time",NULL);
573     errno = 0;
574     precision /= -3;
575     len += precision;
576     sprintf(text,"%.4d %s %.2d %.2d:%.2d:%.2d.%.*d",
577             gmt->tm_year+1900,months[gmt->tm_mon],gmt->tm_mday,
578             gmt->tm_hour,gmt->tm_min,gmt->tm_sec,precision,milli);
579     if (strlen(text) != len)
580         fatal(1,"unable to format current local time",NULL);
581 
582 /* Append the information about the offset, if requested. */
583 
584     if (error >= 0.0) {
585         if (length < len+30)
586             fatal(0,"internal error calling format_time",NULL);
587         errno = 0;
588         sprintf(&text[len]," %c %.*f +/- %.*f secs",(offset > 0.0 ? '-' : '+'),
589 		precision,(offset > 0.0 ? offset : -offset),
590 		precision,dispersion+error);
591         if (strlen(&text[len]) < 22)
592             fatal(1,"unable to format clock correction",NULL);
593     }
594 
595 /* Append the information about the drift, if requested. */
596 
597     if (drifterr >= 0.0) {
598         len = strlen(text);
599         if (length < len+25)
600             fatal(0,"internal error calling format_time",NULL);
601         errno = 0;
602         sprintf(&text[len]," %c %.1f +/- %.1f ppm",
603                 (drift > 0.0 ? '-' : '+'),1.0e6*fabs(drift),
604                 1.0e6*drifterr);
605         if (strlen(&text[len]) < 17)
606             fatal(1,"unable to format clock correction",NULL);
607     }
608 
609 /* It would be better to check for field overflow, but it is a lot of code to
610 trap extremely implausible scenarios.  This will usually stop chaos from
611 spreading. */
612 
613     if (strlen(text) >= length)
614         fatal(0,"internal error calling format_time",NULL);
615 }
616 
617 
618 
619 double reset_clock (double offset, double error, int daemon) {
620 
621 /* Reset the clock, if appropriate, and return the correction actually used.
622 This contains most of the checking for whether changes are worthwhile, except
623 in daemon mode. */
624 
625     double absoff = (offset < 0 ? -offset : offset);
626     char text[50];
627 
628 /* If the correction is large, ask for confirmation before proceeding. */
629 
630     if (absoff > prompt) {
631         if (! daemon && ftty(stdin) && ftty(stdout)) {
632             printf("The time correction is %.3f +/- %.3f+%.3f seconds\n",
633                 offset,dispersion,error);
634             printf("Do you want to correct the time anyway? ");
635             fflush(stdout);
636             if (toupper(getchar()) != 'Y') {
637                 printf("OK - quitting\n");
638                 fatal(0,NULL,NULL);
639             }
640         } else {
641             sprintf(text,"%.3f +/- %.3f+%.3f",offset,dispersion,error);
642             fatal(0,"time correction too large: %s seconds",text);
643         }
644     }
645 
646 /* See if the correction is reasonably reliable and worth making. */
647 
648     if (absoff < (daemon ? 0.5 : 1.0)*minerr) {
649         if (daemon ? verbose > 1 : verbose)
650             fprintf(stderr,"%s: correction %.3f +/- %.3f+%.3f secs - ignored\n",
651                 argv0,offset,dispersion,error);
652         return 0.0;
653     } else if (absoff < 2.0*error) {
654         if (daemon ? verbose > 1 : verbose)
655             fprintf(stderr,
656                 "%s: correction %.3f +/- %.3f+%.3f secs - suppressed\n",
657                 argv0,offset,dispersion,error);
658         return 0.0;
659     }
660 
661 /* Make the correction.  Provide some protection against the previous
662 correction not having completed, but it will rarely help much. */
663 
664     adjust_time(offset,(action == action_reset ? 1 : 0),
665         (daemon ? 2.0*minerr : 0.0));
666     if (daemon ? verbose > 1 : verbose) {
667         format_time(text,50,0.0,-1.0,0.0,-1.0,-10);
668         fprintf(stderr,
669             "%s: time changed by %.3f secs to %s +/- %.3f+%.3f\n",
670             argv0,offset,text,dispersion,error);
671     }
672     return offset;
673 }
674 
675 
676 double estimate_stats (int *a_total, int *a_index, data_record *record,
677     double correction, double *a_disp, double *a_when, double *a_offset,
678     double *a_error, double *a_drift, double *a_drifterr, int *a_wait,
679     int update) {
680 
681 /* This updates the running statistics and returns the best estimate of what to
682 do now.  It returns the timestamp relevant to the correction.  If broadcasts
683 are rare and the drift is large, it will fail - you should then use a better
684 synchronisation method.  It will also fail if something goes severely wrong
685 (e.g. if the local clock is reset by another process or the transmission errors
686 are beyond reason).
687 
688 There is a kludge for synchronisation loss during down time.  If it detects
689 this, it will update only the history data and return zero; this is then
690 handled specially in run_daemon().  While it could correct the offset, this
691 might not always be the right thing to do. */
692 
693     double weight, disp, when, offset, error, drift, drifterr,
694         now, e, w, x, y, z;
695     int total = *a_total, index = *a_index, wait = *a_wait, i;
696     char text[50];
697 
698 /* Correct the previous data and store a new entry in the circular buffer. */
699 
700     for (i = 0; i < total; ++i) {
701         record[i].when += correction;
702         record[i].offset -= correction;
703     }
704     if (update) {
705         record[index].dispersion = *a_disp;
706         record[index].when = *a_when;
707         record[index].offset = *a_offset;
708         if (verbose > 1)
709             fprintf(stderr,"%s: corr=%.3f when=%.3f disp=%.3f off=%.3f",
710                 argv0,correction,*a_when,*a_disp,*a_offset); /* See below */
711         if (operation == op_listen) {
712             if (verbose > 1) fprintf(stderr,"\n");
713             record[index].error = minerr;
714             record[index].weight = 1.0;
715         } else {
716             if (verbose > 1) fprintf(stderr," err=%.3f\n",*a_error);
717             record[index].error = x = *a_error;
718             record[index].weight = 1.0/(x > minerr ? x*x : minerr*minerr);
719         }
720         if (++index >= count) index = 0;
721         *a_index = index;
722         if (++total > count) total = count;
723         *a_total = total;
724         if (verbose > 2)
725             fprintf(stderr,"corr=%.6f tot=%d ind=%d\n",correction,total,index);
726     }
727 
728 /* If there is insufficient data yet, use the latest estimates and return
729 forthwith.  Note that this will not work for broadcasts, but they will be
730 disabled in run_daemon(). */
731 
732     if ((operation == op_listen && total < count && update) || total < 3) {
733         *a_drift = 0.0;
734         *a_drifterr = -1.0;
735         *a_wait = delay;
736         return *a_when;
737     }
738 
739 /* Work out the average time, offset, error etc.  Note that the dispersion is
740 not subject to the central limit theorem.  Unfortunately, the variation in the
741 source's dispersion is our only indication of how consistent its clock is. */
742 
743     disp = weight = when = offset = y = 0.0;
744     for (i = 0; i < total; ++i) {
745         weight += w = record[i].weight;
746         when += w*record[i].when;
747         offset += w*record[i].offset;
748         y += w*record[i].dispersion;
749         if (disp < record[i].dispersion)
750             disp = record[i].dispersion;
751     }
752     when /= weight;
753     offset /= weight;
754     y /= weight;
755     if (verbose > 2)
756         fprintf(stderr,"disp=%.6f wgt=%.3f when=%.6f off=%.6f\n",
757             disp,weight,when,offset);
758 
759 /* If there is enough data, estimate the drift and errors by regression.  Note
760 that it is essential to calculate the mean square error, not the mean error. */
761 
762     error = drift = x = z = 0.0;
763     for (i = 0; i < total; ++i) {
764         w = record[i].weight/weight;
765         x += w*(record[i].when-when)*(record[i].when-when);
766         drift += w*(record[i].when-when)*(record[i].offset-offset);
767         z += w*(record[i].offset-offset)*(record[i].offset-offset);
768         error += w*record[i].error*record[i].error+
769             2.0*w*(record[i].dispersion-y)*(record[i].dispersion-y);
770     }
771     if (verbose > 2)
772         fprintf(stderr,"X2=%.3f XY=%.6f Y2=%.9f E2=%.9f ",x,drift,z,error);
773 
774 /* When calculating the errors, add some paranoia mainly to check for coding
775 errors and complete lunacy, attempting to retry if at all possible.  Because
776 glitches at this point are so common, log a reset even in non-verbose mode.
777 There will be more thorough checks later.  Note that we cannot usefully check
778 the error for broadcasts. */
779 
780     z -= drift*drift/x;
781     if (verbose > 2) fprintf(stderr,"S2=%.9f\n",z);
782     if (! update) {
783         if (z > 1.0e6)
784             fatal(0,"stored data too unreliable for time estimation",NULL);
785     } else if (operation == op_client) {
786         e = error+disp*disp+minerr*minerr;
787         if (z > e) {
788             if (verbose || z >= maxerr*maxerr)
789                 fprintf(stderr,
790                     "%s: excessively high error %.3f > %.3f > %.3f\n",
791                     argv0,sqrt(z),sqrt(e),sqrt(error));
792             if (total <= 1)
793                 return 0.0;
794             else if (z < maxerr*maxerr) {
795                 sprintf(text,"resetting on error %.3g > %.3g",
796                     sqrt(z),sqrt(e));
797                 log_message(text);
798                 return 0.0;
799             } else
800                 fatal(0,"incompatible (i.e. erroneous) timestamps",NULL);
801         } else if (z > error && verbose)
802             fprintf(stderr,
803                 "%s: anomalously high error %.3f > %.3f, but < %.3f\n",
804                 argv0,sqrt(z),sqrt(error),sqrt(e));
805     } else {
806         if (z > maxerr*maxerr)
807             fatal(0,"broadcasts too unreliable for time estimation",NULL);
808     }
809     drift /= x;
810     drifterr = ABSCISSA*sqrt(z/(x*total));
811     error = (operation == op_listen ? minerr : 0.0)+ABSCISSA*sqrt(z/total);
812     if (verbose > 2)
813         fprintf(stderr,"err=%.6f drift=%.6f+/-%.6f\n",error,drift,drifterr);
814     if (error+drifterr*delay > NTP_INSANITY)
815         fatal(0,"unable to get a reasonable drift estimate",NULL);
816 
817 /* Estimate the optimal short-loop period, checking it carefully.  Remember to
818 check that this whole process is likely to be accurate enough and that the
819 delay function may be inaccurate. */
820 
821     wait = delay;
822     x = (drift < 0.0 ? -drift : drift);
823     if (x*delay < 0.5*minerr) {
824         if (verbose > 2) fprintf(stderr,"Drift too small to correct\n");
825     } else if (x < 2.0*drifterr) {
826         if (verbose > 2)
827             fprintf(stderr,"Drift correction suppressed\n");
828     } else {
829         if ((z = drifterr*delay) < 0.5*minerr) z = 0.5*minerr;
830         wait = (x < z/delay ? delay : (int)(z/x+0.5));
831         wait = (int)(delay/(int)(delay/(double)wait+0.999)+0.999);
832         if (wait > delay)
833             fatal(0,"internal error in drift calculation",NULL);
834         if (update && (drift*wait > maxerr || wait < RESET_MIN)) {
835             sprintf(text,"%.6f+/-%.6f",drift,drifterr);
836             fatal(0,"drift correction too large: %s",text);
837         }
838     }
839     if (wait < *a_wait/2) wait = *a_wait/2;
840     if (wait > *a_wait*2) wait = *a_wait*2;
841 
842 /* Now work out what the correction should be, as distinct from what it should
843 have been, remembering that older times are less certain. */
844 
845     now = current_time(JAN_1970);
846     x = now-when;
847     offset += x*drift;
848     error += x*drifterr;
849     for (i = 0; i < total; ++i) {
850         x = now-record[i].when;
851         z = record[i].error+x*drifterr;
852         if (z < error) {
853             when = record[i].when;
854             offset = record[i].offset+x*drift;
855             error = z;
856         }
857     }
858     if (verbose > 2)
859         fprintf(stderr,"now=%.6f when=%.6f off=%.6f err=%.6f wait=%d\n",
860             now,when,offset,error,wait);
861 
862 /* Finally, return the result. */
863 
864     *a_disp = disp;
865     *a_when = when;
866     *a_offset = offset;
867     *a_error = error;
868     *a_drift = drift;
869     *a_drifterr = drifterr;
870     *a_wait = wait;
871     return now;
872 }
873 
874 
875 
876 double correct_drift (double *a_when, double *a_offset, double drift) {
877 
878 /* Correct for the drift since the last time it was done, provided that a long
879 enough time has elapsed.  And do remember to kludge up the time and
880 discrepancy, when appropriate. */
881 
882     double d, x;
883 
884     d = current_time(JAN_1970)-*a_when;
885     *a_when += d;
886     x = *a_offset+d*drift;
887     if (verbose > 2)
888         fprintf(stderr,"Correction %.6f @ %.6f off=%.6f ",x,*a_when,*a_offset);
889     if (d >= waiting && (x < 0.0 ? -x : x) >= 0.5*minerr) {
890         if (verbose > 2) fprintf(stderr,"performed\n");
891         adjust_time(x,(action == action_reset ? 1 : 0),0.5*minerr);
892         *a_offset = 0.0;
893         return x;
894     } else {
895         if (verbose > 2) fprintf(stderr,"ignored\n");
896         *a_offset = x;
897         return 0.0;
898     }
899 }
900 
901 
902 
903 void handle_saving (int operation, int *total, int *index, int *cycle,
904     data_record *record, double *previous, double *when, double *correction) {
905 
906 /* This handles the saving and restoring of the state to a file.  While it is
907 subject to spoofing, this is not a major security problem.  But, out of general
908 paranoia, check everything in sight when restoring.  Note that this function
909 has no external effect if something goes wrong. */
910 
911     struct {
912         data_record record[COUNT_MAX];
913         double previous, when, correction;
914         int operation, delay, count, total, index, cycle, waiting;
915     } buffer;
916     double x, y;
917     int i, j;
918 
919     if (savefile == NULL) return;
920 
921 /* Read the restart file and print its data in diagnostic mode.  Note that some
922 care is necessary to avoid introducing a security exposure - but we trust the
923 C library not to trash the stack on bad numbers! */
924 
925     if (operation == save_read_only || operation == save_read_check) {
926         if (fread(&buffer,sizeof(buffer),1,savefile) != 1 || ferror(savefile)) {
927             if (ferror(savefile))
928                 fatal(1,"unable to read record from daemon save file",NULL);
929             else if (verbose)
930                 fprintf(stderr,"%s: bad daemon restart information\n",argv0);
931             return;
932         }
933         if (verbose > 2) {
934             fprintf(stderr,"Reading prev=%.6f when=%.6f corr=%.6f\n",
935                 buffer.previous,buffer.when,buffer.correction);
936             fprintf(stderr,"op=%d dly=%d cnt=%d tot=%d ind=%d cyc=%d wait=%d\n",
937                 buffer.operation,buffer.delay,buffer.count,buffer.total,
938                 buffer.index,buffer.cycle,buffer.waiting);
939             if (buffer.total < COUNT_MAX)
940                 for (i = 0; i < buffer.total; ++i)
941                     fprintf(stderr,
942                         "disp=%.6f wgt=%.3f when=%.6f off=%.6f err=%.6f\n",
943                         buffer.record[i].dispersion,buffer.record[i].weight,
944                         buffer.record[i].when,buffer.record[i].offset,
945                         buffer.record[i].error);
946         }
947 
948 
949 /* Start checking the data for sanity. */
950 
951         if (buffer.operation == 0 && buffer.delay == 0 && buffer.count == 0) {
952             if (operation < 0)
953                 fatal(0,"the daemon save file has been cleared",NULL);
954             if (verbose)
955                 fprintf(stderr,"%s: restarting from a cleared file\n",argv0);
956             return;
957         }
958         if (operation == save_read_check) {
959             if (buffer.operation != operation || buffer.delay != delay ||
960                     buffer.count != count) {
961                 if (verbose)
962                     fprintf(stderr,"%s: different parameters for restart\n",
963                         argv0);
964                 return;
965             }
966             if (buffer.total < 1 || buffer.total > count || buffer.index < 0 ||
967                     buffer.index >= count || buffer.cycle < 0 ||
968                     buffer.cycle >= count || buffer.correction < -maxerr ||
969                     buffer.correction > maxerr || buffer.waiting < RESET_MIN ||
970                     buffer.waiting > delay || buffer.previous > buffer.when ||
971                     buffer.previous < buffer.when-count*delay ||
972                     buffer.when >= *when) {
973                 if (verbose)
974                     fprintf(stderr,"%s: corrupted restart information\n",argv0);
975                 return;
976             }
977 
978 /* Checking the record is even more tedious. */
979 
980             x = *when;
981             y = 0.0;
982             for (i = 0; i < buffer.total; ++i) {
983                 if (buffer.record[i].dispersion < 0.0 ||
984                         buffer.record[i].dispersion > maxerr ||
985                         buffer.record[i].weight <= 0.0 ||
986                         buffer.record[i].weight > 1.001/(minerr*minerr) ||
987                         buffer.record[i].offset < -count*maxerr ||
988                         buffer.record[i].offset > count*maxerr ||
989                         buffer.record[i].error < 0.0 ||
990                         buffer.record[i].error > maxerr) {
991                     if (verbose)
992                         fprintf(stderr,"%s: corrupted restart record\n",argv0);
993                     return;
994                 }
995                 if (buffer.record[i].when < x) x = buffer.record[i].when;
996                 if (buffer.record[i].when > y) y = buffer.record[i].when;
997             }
998 
999 /* Check for consistency and, finally, whether this is too old. */
1000 
1001             if (y > buffer.when || y-x < (buffer.total-1)*delay ||
1002                     y-x > (buffer.total-1)*count*delay) {
1003                 if (verbose)
1004                     fprintf(stderr,"%s: corrupted restart times\n",argv0);
1005                 return;
1006             }
1007             if (buffer.when < *when-count*delay) {
1008                 if (verbose)
1009                     fprintf(stderr,"%s: restart information too old\n",argv0);
1010                 return;
1011             }
1012         }
1013 
1014 /* If we get here, just copy the data back. */
1015 
1016         memcpy(record,buffer.record,sizeof(buffer.record));
1017         *previous = buffer.previous;
1018         *when = buffer.when;
1019         *correction = buffer.correction;
1020         *total = buffer.total;
1021         *index = buffer.index;
1022         *cycle = buffer.cycle;
1023         waiting = buffer.waiting;
1024         memset(&buffer,0,sizeof(buffer));
1025 
1026 /* Print out the data if requested. */
1027 
1028         if (verbose > 1) {
1029             fprintf(stderr,"%s: prev=%.3f when=%.3f corr=%.3f\n",
1030                 argv0,*previous,*when,*correction);
1031             for (i = 0; i < *total; ++i) {
1032                 if ((j = i+*index-*total) < 0) j += *total;
1033                 fprintf(stderr,"%s: when=%.3f disp=%.3f off=%.3f",
1034                     argv0,record[j].when,record[j].dispersion,record[j].offset);
1035                 if (operation == op_client)
1036                     fprintf(stderr," err=%.3f\n",record[j].error);
1037                 else
1038                     fprintf(stderr,"\n");
1039             }
1040         }
1041 
1042 /* All errors on output are fatal. */
1043 
1044     } else if (operation == save_write) {
1045         memcpy(buffer.record,record,sizeof(buffer.record));
1046         buffer.previous = *previous;
1047         buffer.when = *when;
1048         buffer.correction = *correction;
1049         buffer.operation = operation;
1050         buffer.delay = delay;
1051         buffer.count = count;
1052         buffer.total = *total;
1053         buffer.index = *index;
1054         buffer.cycle = *cycle;
1055         buffer.waiting = waiting;
1056         if (fseek(savefile,0l,SEEK_SET) != 0 ||
1057                 fwrite(&buffer,sizeof(buffer),1,savefile) != 1 ||
1058                 fflush(savefile) != 0 || ferror(savefile))
1059             fatal(1,"unable to write record to daemon save file",NULL);
1060         if (verbose > 2) {
1061             fprintf(stderr,"Writing prev=%.6f when=%.6f corr=%.6f\n",
1062                 *previous,*when,*correction);
1063             fprintf(stderr,"op=%d dly=%d cnt=%d tot=%d ind=%d cyc=%d wait=%d\n",
1064                 operation,delay,count,*total,*index,*cycle,waiting);
1065             if (*total < COUNT_MAX)
1066                 for (i = 0; i < *total; ++i)
1067                     fprintf(stderr,
1068                         "disp=%.6f wgt=%.3f when=%.6f off=%.6f err=%.6f\n",
1069                         record[i].dispersion,record[i].weight,
1070                         record[i].when,record[i].offset,record[i].error);
1071         }
1072 
1073 /* Clearing the save file is similar. */
1074 
1075     } else if (operation == save_clear) {
1076         if (fseek(savefile,0l,SEEK_SET) != 0 ||
1077                 fwrite(&buffer,sizeof(buffer),1,savefile) != 1 ||
1078                 fflush(savefile) != 0 || ferror(savefile))
1079             fatal(1,"unable to clear daemon save file",NULL);
1080     } else
1081         fatal(0,"internal error in handle_saving",NULL);
1082 }
1083 
1084 
1085 
1086 void query_savefile (void) {
1087 
1088 /* This queries a daemon save file. */
1089 
1090     double previous, when, correction = 0.0, offset = 0.0, error = -1.0,
1091         drift = 0.0, drifterr = -1.0;
1092     data_record record[COUNT_MAX];
1093     int total = 0, index = 0, cycle = 0;
1094     char text[100];
1095 
1096 /* This is a few lines stripped out of run_daemon() and slightly hacked. */
1097 
1098     previous = when = current_time(JAN_1970);
1099     if (verbose > 2) {
1100         format_time(text,50,0.0,-1.0,0.0,-1.0,-10);
1101         fprintf(stderr,"Started=%.6f %s\n",when,text);
1102     }
1103     handle_saving(save_read_only,&total,&index,&cycle,record,&previous,&when,
1104         &correction);
1105     estimate_stats(&total,&index,record,correction,&dispersion,
1106         &when,&offset,&error,&drift,&drifterr,&waiting,0);
1107     format_time(text,100,offset,error,drift,drifterr,-10);
1108     printf("%s\n",text);
1109     if (fclose(savefile)) fatal(1,"unable to close daemon save file",NULL);
1110     if (verbose > 2) fprintf(stderr,"Stopped normally\n");
1111     exit(EXIT_SUCCESS);
1112 }
1113 
1114 
1115 
1116 void run_daemon (char *hostnames[], int nhosts, int initial) {
1117 
1118 /* This does not adjust the time between calls to the server, but it does
1119 adjust the time between clock resets.  This function will survive short periods
1120 of server inaccessibility or network glitches, but not long ones, and will then
1121 need restarting manually.
1122 
1123 It is far too complex for a single function, but could really only be
1124 simplified by making most of its variables global or by a similarly horrible
1125 trick.  Oh, for nested scopes as in Algol 68! */
1126 
1127     double history[COUNT_MAX], started, previous, when, correction = 0.0,
1128         weeble = 1.0, accepts = 0.0, rejects = 0.0, flushes = 0.0,
1129         replicates = 0.0, skips = 0.0, offset = 0.0, error = -1.0,
1130         drift = 0.0, drifterr = -1.0, maxoff = 0.0, x;
1131     data_record record[COUNT_MAX];
1132     int total = 0, index = 0, item = 0, rej_level = 0, rep_level = 0,
1133         cycle = 0, retry = 1, i, j, k;
1134     unsigned char transmit[NTP_PACKET_MIN];
1135     ntp_data data;
1136     char text[100];
1137 
1138 /* After initialising, restore from a previous run if possible.  Note that
1139 only a few of the variables are actually needed to control the operation and
1140 the rest are mainly for diagnostics. */
1141 
1142     started = previous = when = current_time(JAN_1970);
1143     if (verbose > 2) {
1144         format_time(text,50,0.0,-1.0,0.0,-1.0,-10);
1145         fprintf(stderr,"Started=%.6f %s\n",when,text);
1146     }
1147     if (initial) {
1148         handle_saving(save_read_check,&total,&index,&cycle,record,
1149             &previous,&when,&correction);
1150         cycle = (nhosts > 0 ? cycle%nhosts : 0);
1151         if (total > 0 && started-previous < delay) {
1152             if (verbose > 2) fprintf(stderr,"Last packet too recent\n");
1153             retry = 0;
1154         }
1155         if (verbose > 2)
1156             fprintf(stderr,"prev=%.6f when=%.6f retry=%d\n",
1157                 previous,when,retry);
1158         for (i = 0; i < nhosts; ++i) open_socket(i,hostnames[i],delay);
1159         if (action != action_display) {
1160             set_lock(1);
1161             locked = 1;
1162         }
1163     }
1164     dispersion = 0.0;
1165     attempts = 0;
1166     for (i = 0; i < count; ++i) history[i] = 0.0;
1167     while (1) {
1168 
1169 /* Print out a reasonable amount of diagnostics, rather like a server.  Note
1170 that it may take a little time, but shouldn't affect the estimates much.  Then
1171 check that we aren't in a failing loop. */
1172 
1173         if (verbose > 2) fprintf(stderr,"item=%d rej=%d\n",item,rej_level);
1174         x = current_time(JAN_1970)-started;
1175         if (verbose &&
1176                 x/3600.0+accepts+rejects+flushes+replicates+skips >= weeble) {
1177             weeble *= WEEBLE_FACTOR;
1178             x -= 3600.0*(i = (int)(x/3600.0));
1179             x -= 60.0*(j = (int)(x/60.0));
1180             if (i > 0)
1181                 fprintf(stderr,"%s: after %d hours %d mins ",argv0,i,j);
1182             else if (j > 0)
1183                 fprintf(stderr,"%s: after %d mins %.0f secs ",argv0,j,x);
1184             else
1185                 fprintf(stderr,"%s: after %.1f secs ",argv0,x);
1186             fprintf(stderr,"acc. %.0f rej. %.0f flush %.0f",
1187                 accepts,rejects,flushes);
1188             if (operation == op_listen)
1189                 fprintf(stderr," rep. %.0f skip %.0f",replicates,skips);
1190             fprintf(stderr," max.off. %.3f corr. %.3f\n",maxoff,correction);
1191             format_time(text,100,offset,error,drift,drifterr,-10);
1192             fprintf(stderr,"%s: %s\n",argv0,text);
1193             maxoff = 0.0;
1194         }
1195         if (current_time(JAN_1970)-previous > count*delay) {
1196             if (verbose)
1197                 fprintf(stderr,"%s: no packets in too long a period\n",argv0);
1198             return;
1199         }
1200 
1201 /* Listen for the next broadcast packet.  This allows up to ETHERNET_MAX
1202 replications per packet, for systems with multiple addresses for receiving
1203 broadcasts; the only reason for a limit is to protect against broken NTP
1204 servers always returning the same time. */
1205 
1206         if (operation == op_listen) {
1207             flushes += flush_socket(0);
1208             if (read_packet(0,&data,&offset,&error)) {
1209                 ++rejects;
1210                 if (++rej_level > count)
1211                     fatal(0,"too many bad or lost packets",NULL);
1212                 if (action != action_display && drifterr >= 0.0) {
1213                     correction += correct_drift(&when,&offset,drift);
1214                     handle_saving(save_write,&total,&index,&cycle,record,
1215                         &previous,&when,&correction);
1216                 }
1217                 continue;
1218             }
1219             if ((rej_level -= (count < 5 ? count : 5)) < 0) rej_level = 0;
1220             x = data.transmit;
1221             for (i = 0; i < count; ++i)
1222                 if (x == history[i]) {
1223                     ++replicates;
1224                     if (++rep_level > ETHERNET_MAX)
1225                         fatal(0,"too many replicated packets",NULL);
1226                     goto continue1;
1227                 }
1228             rep_level = 0;
1229             history[item] = x;
1230             if (++item >= count) item = 0;
1231 
1232 /* Accept a packet only after a long enough period has elapsed. */
1233 
1234             when = data.current;
1235             if (! retry && when < previous+delay) {
1236                 if (verbose > 2) fprintf(stderr,"Skipping too recent packet\n");
1237                 ++skips;
1238                 continue;
1239             }
1240             retry = 0;
1241             if (verbose > 2)
1242                 fprintf(stderr,"Offset=%.6f @ %.6f disp=%.6f\n",
1243                     offset,when,dispersion);
1244 
1245 /* Handle the client/server model.  It keeps a record of transmitted times,
1246 mainly out of paranoia.  The waiting time is kludged up to attempt to provide
1247 reasonable resilience against both lost packets and dead servers.  But it
1248 won't handle much of either, and will stop after a while, needing manual
1249 restarting.  Running it under cron is the best approach. */
1250 
1251         } else {
1252             if (! retry) {
1253                if (verbose > 2) fprintf(stderr,"Sleeping for %d\n",waiting);
1254                do_nothing(waiting);
1255             }
1256             make_packet(&data,NTP_CLIENT);
1257             outgoing[item] = data.transmit;
1258             if (++item >= 2*count) item = 0;
1259             if (attempts < 2*count) ++attempts;
1260             if (verbose > 2) {
1261                 fprintf(stderr,"Outgoing packet on socket %d:\n",cycle);
1262                 display_data(&data);
1263             }
1264             pack_ntp(transmit,NTP_PACKET_MIN,&data);
1265             if (verbose > 2) display_packet(transmit,NTP_PACKET_MIN);
1266             flushes += flush_socket(cycle);
1267             write_socket(cycle,transmit,NTP_PACKET_MIN);
1268 
1269 /* Read the packet and check that it is an appropriate response.  Because this
1270 is rather more numerically sensitive than simple resynchronisation, reject all
1271 very inaccurate packets.  Be careful if you modify this, because the error
1272 handling is rather nasty to avoid replicating code. */
1273 
1274             k = read_packet(cycle,&data,&offset,&error);
1275             if (++cycle >= nhosts) cycle = 0;
1276             if (! k)
1277                 when = (data.originate+data.current)/2.0;
1278             else if (action != action_display && drifterr >= 0.0) {
1279                 correction += correct_drift(&when,&offset,drift);
1280                 handle_saving(save_write,&total,&index,&cycle,record,
1281                     &previous,&when,&correction);
1282             }
1283             if (! k && ! retry && when < previous+delay-2) {
1284                 if (verbose)
1285                     fprintf(stderr,"%s: packets out of order on socket %d\n",
1286                         argv0,cycle);
1287                 k = 1;
1288             }
1289             if (! k && data.current-data.originate > maxerr) {
1290                 if (verbose)
1291                     fprintf(stderr,
1292                         "%s: very slow response rejected on socket %d\n",
1293                         argv0,cycle);
1294                 k = 1;
1295             }
1296 
1297 /* Count the number of rejected packets and fail if there are too many. */
1298 
1299             if (k) {
1300                 ++rejects;
1301                 if (++rej_level > count)
1302                     fatal(0,"too many bad or lost packets",NULL);
1303                 else {
1304                     retry = 1;
1305                     continue;
1306                 }
1307             } else
1308                 retry = 0;
1309             if ((rej_level -= (count < 5 ? count : 5)) < 0) rej_level = 0;
1310             if (verbose > 2)
1311                 fprintf(stderr,"Offset=%.6f+/-%.6f @ %.6f disp=%.6f\n",
1312                     offset,error,when,dispersion);
1313         }
1314 
1315 /* Calculate the statistics, and display the results or make the initial
1316 correction.  Note that estimate_stats() will return zero if a timestamp
1317 indicates synchronisation loss (usually due to down time or a change of server,
1318 somewhere upstream), and that the recovery operation is unstructured, so great
1319 care should be taken when modifying it.  Also, we want to clear the saved state
1320 is the statistics are bad. */
1321 
1322         handle_saving(save_clear,&total,&index,&cycle,record,&previous,&when,
1323             &correction);
1324         ++accepts;
1325         dispersion = data.dispersion;
1326         previous = when =
1327             estimate_stats(&total,&index,record,correction,&dispersion,
1328                 &when,&offset,&error,&drift,&drifterr,&waiting,1);
1329         if (verbose > 2) {
1330             fprintf(stderr,"tot=%d ind=%d dis=%.3f when=%.3f off=%.3f ",
1331                 total,index,dispersion,when,offset);
1332             fprintf(stderr,"err=%.3f wait=%d\n",error,waiting);
1333         }
1334         if (when == 0.0) return;
1335         x = (maxoff < 0.0 ? -maxoff : maxoff);
1336         if ((offset < 0.0 ? -offset : offset) > x) maxoff = offset;
1337         correction = 0.0;
1338         if (operation == op_client || accepts >= count) {
1339             if (action == action_display) {
1340                 format_time(text,100,offset,error,drift,drifterr,-10);
1341                 printf("%s\n",text);
1342             } else {
1343                 x = reset_clock(offset,error,1);
1344                 correction += x;
1345                 offset -= x;
1346             }
1347         } else
1348             waiting = delay;
1349         handle_saving(save_write,&total,&index,&cycle,record,&previous,&when,
1350             &correction);
1351 
1352 /* Now correct the clock for a while, before getting another packet and
1353 updating the statistics. */
1354 
1355         while (when < previous+delay-waiting) {
1356             do_nothing(waiting);
1357             if (action == action_display)
1358                 when += waiting;
1359             else {
1360                 correction += correct_drift(&when,&offset,drift);
1361                 handle_saving(save_write,&total,&index,&cycle,record,
1362                     &previous,&when,&correction);
1363             }
1364         }
1365 continue1: ;
1366     }
1367 }
1368 
1369 
1370 
1371 void run_client (char *hostnames[], int nhosts) {
1372 
1373 /* Get enough responses to do something with; or not, as the case may be.  Note
1374 that it allows for half of the packets to be bad, so may make up to twice as
1375 many attempts as specified by the -c value.  The deadline checking is merely
1376 paranoia, to protect against broken signal handling - it cannot easily be
1377 triggered if the signal handling works. */
1378 
1379     double history[COUNT_MAX], guesses[COUNT_MAX], offset, error, deadline,
1380         a, b, x, y;
1381     int precs[COUNT_MAX], precision = 0;
1382     int accepts = 0, rejects = 0, flushes = 0, replicates = 0, cycle = 0, k;
1383     unsigned char transmit[NTP_PACKET_MIN];
1384     ntp_data data;
1385     char text[100];
1386 
1387     if (verbose > 2) {
1388         format_time(text,50,0.0,-1.0,0.0,-1.0,-10);
1389         fprintf(stderr,"Started=%.6f %s\n",current_time(JAN_1970),text);
1390     }
1391     for (k = 0; k < nhosts; ++k) open_socket(k,hostnames[k],delay);
1392     if (action != action_display) {
1393         set_lock(1);
1394         locked = 1;
1395     }
1396     attempts = 0;
1397     deadline = current_time(JAN_1970)+delay;
1398 
1399 /* Listen to broadcast packets and select the best (i.e. earliest).  This will
1400 be sensitive to a bad NTP broadcaster, but I believe such things are very rare
1401 in practice.  In any case, if you have one, it is probably the only one on your
1402 subnet, so you are knackered!  This allows up to ETHERNET_MAX replications per
1403 packet, for systems with multiple addresses for receiving broadcasts; the only
1404 reason for a limit is to protect against broken NTP servers always returning
1405 the same time. */
1406 
1407     if (operation == op_listen) {
1408         while (accepts < count) {
1409             if (current_time(JAN_1970) > deadline)
1410                 fatal(0,"not enough valid broadcasts received in time",NULL);
1411             flushes += flush_socket(0);
1412             if (read_packet(0,&data,&x,&y)) {
1413                 if (++rejects > count)
1414                     fatal(0,"too many bad or lost packets",NULL);
1415                 else
1416                     continue;
1417             } else {
1418                 a = data.transmit;
1419                 for (k = 0; k < accepts; ++k)
1420                     if (a == history[k]) {
1421                         if (++replicates > ETHERNET_MAX*count)
1422                             fatal(0,"too many replicated packets",NULL);
1423                         goto continue1;
1424                     }
1425                 history[accepts] = a;
1426 		precs[accepts] = data.precision;
1427                 guesses[accepts++] = x;
1428             }
1429             if (verbose > 2)
1430                 fprintf(stderr,"Offset=%.6f disp=%.6f\n",x,dispersion);
1431             else if (verbose > 1)
1432                 fprintf(stderr,"%s: offset=%.3f disp=%.3f\n",
1433                     argv0,x,dispersion);
1434 
1435 /* Note that bubblesort IS a good method for this amount of data.  */
1436 
1437             for (k = accepts-2; k >= 0; --k)
1438                 if (guesses[k] < guesses[k+1])
1439                     break;
1440                 else {
1441                     x = guesses[k];
1442                     guesses[k] = guesses[k+1];
1443                     guesses[k+1] = x;
1444 		    precision = precs[k];
1445 		    precs[k] = precs[k+1];
1446 		    precs[k+1] = precision;
1447                 }
1448 continue1:  ;
1449         }
1450         offset = guesses[0];
1451 	precision = precs[0];
1452         error = minerr+guesses[count <= 5 ? count-1 : 5]-offset;
1453         if (verbose > 2)
1454             fprintf(stderr,"accepts=%d rejects=%d flushes=%d replicates=%d\n",
1455                 accepts,rejects,flushes,replicates);
1456 
1457 /* Handle the client/server model.  It keeps a record of transmitted times,
1458 mainly out of paranoia. */
1459 
1460     } else {
1461         offset = 0.0;
1462 	precision = 0;
1463         error = NTP_INSANITY;
1464         while (accepts < count && attempts < 2*count) {
1465             if (current_time(JAN_1970) > deadline)
1466                 fatal(0,"not enough valid responses received in time",NULL);
1467             make_packet(&data,NTP_CLIENT);
1468             precs[attempts] = data.precision;
1469             outgoing[attempts++] = data.transmit;
1470             if (verbose > 2) {
1471                 fprintf(stderr,"Outgoing packet on socket %d:\n",cycle);
1472                 display_data(&data);
1473             }
1474             pack_ntp(transmit,NTP_PACKET_MIN,&data);
1475             if (verbose > 2) display_packet(transmit,NTP_PACKET_MIN);
1476             flushes += flush_socket(cycle);
1477             write_socket(cycle,transmit,NTP_PACKET_MIN);
1478             if (read_packet(cycle,&data,&x,&y)) {
1479                 if (++rejects > count)
1480                     fatal(0,"too many bad or lost packets",NULL);
1481                 else
1482                     continue;
1483             } else
1484                 ++accepts;
1485             if (++cycle >= nhosts) cycle = 0;
1486 
1487 /* Work out the most accurate time, and check that it isn't more accurate than
1488 the results warrant. */
1489 
1490             if (verbose > 2)
1491                 fprintf(stderr,"Offset=%.6f+/-%.6f disp=%.6f\n",x,y,dispersion);
1492             else if (verbose > 1)
1493                 fprintf(stderr,"%s: offset=%.3f+/-%.3f disp=%.3f\n",
1494                     argv0,x,y,dispersion);
1495             if ((a = x-offset) < 0.0) a = -a;
1496             if (accepts <= 1) a = 0.0;
1497             b = error+y;
1498             if (y < error) {
1499                 offset = x;
1500                 error = y;
1501 		precision = data.precision;
1502             }
1503             if (verbose > 2)
1504                 fprintf(stderr,"best=%.6f+/-%.6f\n",offset,error);
1505             if (a > b) {
1506                 sprintf(text,"%d",cycle);
1507                 fatal(0,"inconsistent times got from NTP server on socket %s",
1508                     text);
1509             }
1510             if (error <= minerr) break;
1511         }
1512         if (verbose > 2)
1513             fprintf(stderr,"accepts=%d rejects=%d flushes=%d\n",
1514                 accepts,rejects,flushes);
1515     }
1516 
1517 /* Tidy up the socket, issues diagnostics and perform the action. */
1518 
1519     for (k = 0; k < nhosts; ++k) close_socket(k);
1520     if (accepts == 0) fatal(0,"no acceptable packets received",NULL);
1521     if (error > NTP_INSANITY)
1522         fatal(0,"unable to get a reasonable time estimate",NULL);
1523     if (verbose > 2)
1524         fprintf(stderr,"Correction: %.6f +/- %.6f disp=%.6f\n",
1525             offset,error,dispersion);
1526     if (action == action_display) {
1527         format_time(text,75,offset,error,0.0,-1.0,precision);
1528         printf("%s\n",text);
1529     } else
1530         (void)reset_clock(offset,error,0);
1531     if (locked) set_lock(0);
1532     if (verbose > 2) fprintf(stderr,"Stopped normally\n");
1533     exit(EXIT_SUCCESS);
1534 }
1535 
1536 
1537 
1538 int main (int argc, char *argv[]) {
1539 
1540 /* This is the entry point and all that.  It decodes the arguments and calls
1541 one of the specialised routines to do the work. */
1542 
1543     char *hostnames[MAX_SOCKETS], *savename = NULL;
1544     int daemon = 0, nhosts = 0, help = 0, args = argc-1, k;
1545     char c;
1546 
1547     if (argv[0] == NULL || argv[0][0] == '\0')
1548         argv0 = "sntp";
1549     else if ((argv0 = strrchr(argv[0],'/')) != NULL)
1550         ++argv0;
1551     else
1552         argv0 = argv[0];
1553 
1554     setvbuf(stdout,NULL,_IOLBF,BUFSIZ);
1555     setvbuf(stderr,NULL,_IOLBF,BUFSIZ);
1556 
1557     if (INT_MAX < 2147483647) fatal(0,"sntp requires >= 32-bit ints",NULL);
1558     if (DBL_EPSILON > 1.0e-13)
1559         fatal(0,"sntp requires doubles with eps <= 1.0e-13",NULL);
1560     for (k = 0; k < MAX_SOCKETS; ++k) hostnames[k] = NULL;
1561 
1562 /* Decode the arguments. */
1563 
1564     while (argc > 1) {
1565         k = 1;
1566 	if (strcmp(argv[1],"-4") == 0)
1567 	    preferred_family(PREF_FAM_INET);
1568 	else if (strcmp(argv[1],"-6") == 0)
1569 	    preferred_family(PREF_FAM_INET6);
1570         else if (strcmp(argv[1],"-u") == 0)
1571             ++unprivport;
1572         else if (strcmp(argv[1],"-q") == 0 && action == 0)
1573             action = action_query;
1574         else if (strcmp(argv[1],"-r") == 0 && action == 0)
1575             action = action_reset;
1576         else if (strcmp(argv[1],"-a") == 0 && action == 0)
1577             action = action_adjust;
1578         else if (strcmp(argv[1],"-l") == 0 && lockname == NULL && argc > 2) {
1579             lockname = argv[2];
1580             k = 2;
1581         } else if ((strcmp(argv[1],"-x") == 0) &&
1582                 daemon == 0) {
1583             if (argc > 2 && sscanf(argv[2],"%d%c",&daemon,&c) == 1) {
1584                 if (daemon < 1 || daemon > 1440)
1585                     fatal(0,"%s option value out of range",argv[1]);
1586                 k = 2;
1587             } else
1588                 daemon = 300;
1589         } else if (strcmp(argv[1],"-f") == 0 && savename == NULL && argc > 2) {
1590             savename = argv[2];
1591             k = 2;
1592         } else if ((strcmp(argv[1],"--help") == 0 ||
1593                     strcmp(argv[1],"-h") == 0 || strcmp(argv[1],"-?") == 0) &&
1594                 help == 0)
1595             help = 1;
1596         else if (strcmp(argv[1],"-v") == 0 && verbose == 0)
1597             verbose = 1;
1598         else if (strcmp(argv[1],"-V") == 0 && verbose == 0)
1599             verbose = 2;
1600         else if (strcmp(argv[1],"-W") == 0 && verbose == 0)
1601             verbose = 3;
1602         else if (strcmp(argv[1],"-e") == 0 && minerr == 0.0 && argc > 2) {
1603             if (sscanf(argv[2],"%lf%c",&minerr,&c) != 1) syntax(1);
1604             if (minerr <= 0.000999999 || minerr > 1.0)
1605                 fatal(0,"%s option value out of range","-e");
1606             k = 2;
1607         } else if (strcmp(argv[1],"-E") == 0 && maxerr == 0.0 && argc > 2) {
1608             if (sscanf(argv[2],"%lf%c",&maxerr,&c) != 1) syntax(1);
1609             if (maxerr < 1.0 || maxerr > 60.0)
1610                 fatal(0,"%s option value out of range","-E");
1611             k = 2;
1612         } else if (strcmp(argv[1],"-P") == 0 && prompt == 0.0 && argc > 2) {
1613             if (strcmp(argv[2],"no") == 0)
1614                 prompt = (double)INT_MAX;
1615             else {
1616                 if (sscanf(argv[2],"%lf%c",&prompt,&c) != 1) syntax(1);
1617                 if (prompt < 1.0 || prompt > 3600.0)
1618                     fatal(0,"%s option value out of range","-p");
1619             }
1620             k = 2;
1621         } else if (strcmp(argv[1],"-d") == 0 && delay == 0 && argc > 2) {
1622             if (sscanf(argv[2],"%d%c",&delay,&c) != 1) syntax(1);
1623             if (delay < 1 || delay > 3600)
1624                 fatal(0,"%s option value out of range","-d");
1625             k = 2;
1626         } else if (strcmp(argv[1],"-c") == 0 && count == 0 && argc > 2) {
1627             if (sscanf(argv[2],"%d%c",&count,&c) != 1) syntax(1);
1628             if (count < 1 || count > COUNT_MAX)
1629                 fatal(0,"%s option value out of range","-c");
1630             k = 2;
1631         } else
1632             break;
1633         argc -= k;
1634         argv += k;
1635     }
1636 
1637 /* Check the arguments for consistency and set the defaults. */
1638 
1639     if (action == action_query) {
1640         if (argc != 1 || minerr != 0.0 || maxerr != 0.0 || count != 0 ||
1641                 delay != 0 || daemon != 0 || prompt != 0.0 || lockname != NULL)
1642             syntax(1);
1643     } else {
1644         if (argc < 1 || argc > MAX_SOCKETS || (daemon != 0 && delay != 0))
1645             syntax(1);
1646         if ((prompt || lockname != NULL) &&
1647                 action != action_reset && action != action_adjust)
1648             syntax(1);
1649         if (count > 0 && count < argc-1)
1650             fatal(0,"-c value less than number of addresses",NULL);
1651        if (argc > 1) {
1652             operation = op_client;
1653             for (k = 1; k < argc; ++k) {
1654                 if (argv[k][0] == '\0' || argv[k][0] == '-')
1655                     fatal(0,"invalid Internet address '%s'",argv[k]);
1656                 hostnames[k-1] = argv[k];
1657             }
1658             nhosts = argc-1;
1659         } else {
1660             operation = op_listen;
1661             nhosts = 0;
1662         }
1663         if (action == 0) action = action_display;
1664         if (minerr <= 0.0) minerr = (operation == op_listen ? 0.5 : 0.1);
1665         if (maxerr <= 0.0) maxerr = 5.0;
1666         if (count == 0) count = (argc-1 < 5 ? 5 : argc-1);
1667         if ((argc == 1 || (daemon != 0 && action != action_query)) && count < 5)
1668             fatal(0,"at least 5 packets needed in this mode",NULL);
1669         if ((action == action_reset || action == action_adjust) &&
1670                 lockname == NULL)
1671             lockname = LOCKNAME;
1672 
1673 /* The '-x' option changes the implications of many other settings, though this
1674 is not usually apparent to the caller.  Most of the time delays are to ensure
1675 that stuck states terminate, and do not affect the result. */
1676 
1677         if (daemon != 0) {
1678             if (minerr >= maxerr || maxerr >= daemon)
1679                 fatal(0,"values not in order -e < -E < -x",NULL);
1680             waiting = delay = daemon *= 60;
1681         } else {
1682             if (savename != NULL)
1683                 fatal(0,"-f can be specified only with -x",NULL);
1684             if (delay == 0)
1685                 delay = (operation == op_listen ? 300 :
1686                         (2*count >= 15 ? 2*count+1 :15));
1687             if (operation == op_listen) {
1688                 if (minerr >= maxerr || maxerr >= delay/count)
1689                     fatal(0,"values not in order -e < -E < -d/-c",NULL);
1690             } else {
1691                 if (minerr >= maxerr || maxerr >= delay)
1692                     fatal(0,"values not in order -e < -E < -d",NULL);
1693             }
1694             if (2*count >= delay) fatal(0,"-c must be less than half -d",NULL);
1695             waiting = delay/count;
1696         }
1697         if (prompt == 0.0) prompt = 30.0;
1698     }
1699     if ((daemon || action == action_query) && savename == NULL)
1700         savename = SAVENAME;
1701 
1702 /* Diagnose where we are, if requested, and separate out the classes of
1703 operation.  The calls do not return. */
1704 
1705     if (help) syntax(args == 1);
1706     if (verbose) {
1707         fprintf(stderr,"%s options: a=%d v=%d e=%.3f E=%.3f P=%.3f\n",
1708             argv0,action,verbose,minerr,maxerr,prompt);
1709         fprintf(stderr,"    d=%d c=%d %c=%d op=%d l=%s f=%s",
1710             delay,count,'x',daemon,operation,
1711             (lockname == NULL ? "" : lockname),
1712             (savename == NULL ? "" : savename));
1713         for (k = 0; k < MAX_SOCKETS; ++k)
1714             if (hostnames[k] != NULL) fprintf(stderr," %s",hostnames[k]);
1715         fprintf(stderr,"\n");
1716     }
1717     if (nhosts == 0) nhosts = 1;    /* Kludge for broadcasts */
1718     if (action == action_query) {
1719         if (savename == NULL || savename[0] == '\0')
1720             fatal(0,"no daemon save file specified",NULL);
1721         else if ((savefile = fopen(savename,"rb")) == NULL)
1722             fatal(0,"unable to open the daemon save file",NULL);
1723         query_savefile();
1724     } else if (daemon != 0) {
1725         if (savename != NULL && savename[0] != '\0' &&
1726                 (savefile = fopen(savename,"rb+")) == NULL &&
1727                 (savefile = fopen(savename,"wb+")) == NULL)
1728             fatal(0,"unable to open the daemon save file",NULL);
1729         run_daemon(hostnames,nhosts,1);
1730         while (1) run_daemon(hostnames,nhosts,0);
1731     } else
1732         run_client(hostnames,nhosts);
1733     fatal(0,"internal error at end of main",NULL);
1734     return EXIT_FAILURE;
1735 }
1736