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  TCP/IP Library Reference
9
 
10
 
11
  
12
    getdomainname
13
    
14
GETDOMAINNAME(3)        System Library Functions Manual       GETDOMAINNAME(3)
15
 
16
NAME
17
     getdomainname, setdomainname - get/set YP domain name of current host
18
 
19
SYNOPSIS
20
     #include <unistd.h>
21
 
22
     int
23
     getdomainname(char *name, size_t namelen);
24
 
25
     int
26
     setdomainname(const char *name, size_t namelen);
27
 
28
DESCRIPTION
29
     The getdomainname() function returns the YP domain name for the current
30
     processor, as previously set by setdomainname().  The parameter namelen
31
     specifies the size of the name array.  If insufficient space is provided,
32
     the returned name is truncated.  The returned name is always null termi-
33
     nated.
34
 
35
     setdomainname() sets the domain name of the host machine to be name,
36
     which has length namelen.  This call is restricted to the superuser and
37
     is normally used only when the system is bootstrapped.
38
 
39
RETURN VALUES
40
     If the call succeeds a value of 0 is returned.  If the call fails, a
41
     value of -1 is returned and an error code is placed in the global vari-
42
     able errno.
43
 
44
ERRORS
45
     The following errors may be returned by these calls:
46
 
47
     [EFAULT]           The name or namelen parameter gave an invalid address.
48
 
49
     [EPERM]            The caller tried to set the domain name and was not
50
                        the superuser.
51
 
52
SEE ALSO
53
     domainname(1), gethostid(3), gethostname(3), sysctl(3), sysctl(8), yp(8)
54
 
55
BUGS
56
     Domain names are limited to MAXHOSTNAMELEN (from <sys/param.h>) charac-
57
     ters, currently 256.  This includes the terminating NUL character.
58
 
59
     If the buffer passed to getdomainname() is too small, other operating
60
     systems may not guarantee termination with NUL.
61
 
62
HISTORY
63
     The getdomainname function call appeared in SunOS 3.x.
64
 
65
BSD                               May 6, 1994                              BSD
66
    
67
  
68
 
69
  
70
    gethostname
71
    
72
GETHOSTNAME(3)          System Library Functions Manual         GETHOSTNAME(3)
73
 
74
NAME
75
     gethostname, sethostname - get/set name of current host
76
 
77
SYNOPSIS
78
     #include <unistd.h>
79
 
80
     int
81
     gethostname(char *name, size_t namelen);
82
 
83
     int
84
     sethostname(const char *name, size_t namelen);
85
 
86
DESCRIPTION
87
     The gethostname() function returns the standard host name for the current
88
     processor, as previously set by sethostname().  The parameter namelen
89
     specifies the size of the name array.  If insufficient space is provided,
90
     the returned name is truncated.  The returned name is always null termi-
91
     nated.
92
 
93
     sethostname() sets the name of the host machine to be name, which has
94
     length namelen.  This call is restricted to the superuser and is normally
95
     used only when the system is bootstrapped.
96
 
97
RETURN VALUES
98
     If the call succeeds a value of 0 is returned.  If the call fails, a
99
     value of -1 is returned and an error code is placed in the global vari-
100
     able errno.
101
 
102
ERRORS
103
     The following errors may be returned by these calls:
104
 
105
     [EFAULT]           The name or namelen parameter gave an invalid address.
106
 
107
     [EPERM]            The caller tried to set the hostname and was not the
108
                        superuser.
109
 
110
SEE ALSO
111
     hostname(1), getdomainname(3), gethostid(3), sysctl(3), sysctl(8), yp(8)
112
 
113
STANDARDS
114
     The gethostname() function call conforms to X/Open Portability Guide
115
     Issue 4.2 (``XPG4.2'').
116
 
117
HISTORY
118
     The gethostname() function call appeared in 4.2BSD.
119
 
120
BUGS
121
     Host names are limited to MAXHOSTNAMELEN (from <sys/param.h>) characters,
122
     currently 256.  This includes the terminating NUL character.
123
 
124
     If the buffer passed to gethostname() is smaller than MAXHOSTNAMELEN,
125
     other operating systems may not guarantee termination with NUL.
126
 
127
BSD                              June 4, 1993                              BSD
128
    
129
  
130
 
131
  
132
    byteorder
133
    
134
BYTEORDER(3)            System Library Functions Manual           BYTEORDER(3)
135
 
136
NAME
137
     htonl, htons, ntohl, ntohs, htobe32, htobe16, betoh32, betoh16, htole32,
138
     htole16, letoh32, letoh16, swap32, swap16 - convert values between dif-
139
     ferent byte orderings
140
 
141
SYNOPSIS
142
     #include <sys/types.h>
143
     #include <machine/endian.h>
144
 
145
     u_int32_t
146
     htonl(u_int32_t host32);
147
 
148
     u_int16_t
149
     htons(u_int16_t host16);
150
 
151
     u_int32_t
152
     ntohl(u_int32_t net32);
153
 
154
     u_int16_t
155
     ntohs(u_int16_t net16);
156
 
157
     u_int32_t
158
     htobe32(u_int32_t host32);
159
 
160
     u_int16_t
161
     htobe16(u_int16_t host16);
162
 
163
     u_int32_t
164
     betoh32(u_int32_t big32);
165
 
166
     u_int16_t
167
     betoh16(u_int16_t big16);
168
 
169
     u_int32_t
170
     htole32(u_int32_t host32);
171
 
172
     u_int16_t
173
     htole16(u_int16_t host16);
174
 
175
     u_int32_t
176
     letoh32(u_int32_t little32);
177
 
178
     u_int16_t
179
     letoh16(u_int16_t little16);
180
 
181
     u_int32_t
182
     swap32(u_int32_t val32);
183
 
184
     u_int16_t
185
     swap16(u_int16_t val16);
186
 
187
DESCRIPTION
188
     These routines convert 16- and 32-bit quantities between different byte
189
     orderings.  The ``swap'' functions reverse the byte ordering of the given
190
     quantity, the others converts either from/to the native byte order used
191
     by the host to/from either little- or big-endian (a.k.a network) order.
192
 
193
     Apart from the swap functions, the names can be described by this form:
194
     {src-order}to{dst-order}{size}.  Both {src-order} and {dst-order} can
195
     take the following forms:
196
 
197
           h    Host order.
198
           n    Network order (big-endian).
199
           be   Big-endian (most significant byte first).
200
           le   Little-endian (least significant byte first).
201
 
202
     One of the specified orderings must be `h'.  {size} will take these
203
     forms:
204
 
205
           l  Long (32-bit, used in conjunction with forms involving `n').
206
           s  Short (16-bit, used in conjunction with forms involving `n').
207
           16
208
              16-bit.
209
           32
210
              32-bit.
211
 
212
     The swap functions are of the form: swap{size}.
213
 
214
     Names involving `n' convert quantities between network byte order and
215
     host byte order.  The last letter (`s' or `l') is a mnemonic for the tra-
216
     ditional names for such quantities, short and long, respectively.  Today,
217
     the C concept of short and long integers need not coincide with this tra-
218
     ditional misunderstanding.  On machines which have a byte order which is
219
     the same as the network order, routines are defined as null macros.
220
 
221
     The functions involving either ``be'', ``le'', or ``swap'' use the num-
222
     bers 16 and 32 for specifying the bitwidth of the quantities they operate
223
     on.  Currently all supported architectures are either big- or little-
224
     endian so either the ``be'' or ``le'' variants are implemented as null
225
     macros.
226
 
227
     The routines mentioned above which have either {src-order} or {dst-order}
228
     set to `n' are most often used in conjunction with Internet addresses and
229
     ports as returned by gethostbyname(3) and getservent(3).
230
 
231
SEE ALSO
232
     gethostbyname(3), getservent(3)
233
 
234
HISTORY
235
     The byteorder functions appeared in 4.2BSD.
236
 
237
BUGS
238
     On the vax, alpha, i386, and so far mips, bytes are handled backwards
239
     from most everyone else in the world.  This is not expected to be fixed
240
     in the near future.
241
 
242
BSD                              June 4, 1993                              BSD
243
    
244
  
245
 
246
  
247
    ethers
248
    
249
ETHERS(3)               System Library Functions Manual              ETHERS(3)
250
 
251
NAME
252
     ether_aton, ether_ntoa, ether_addr, ether_ntohost, ether_hostton,
253
     ether_line - get ethers entry
254
 
255
SYNOPSIS
256
     #include <netinet/if_ether.h>
257
 
258
     char *
259
     ether_ntoa(struct ether_addr *e);
260
 
261
     struct ether_addr *
262
     ether_aton(char *s);
263
 
264
     int
265
     ether_ntohost(char *hostname, struct ether_addr *e);
266
 
267
     int
268
     ether_hostton(char *hostname, struct ether_addr *e);
269
 
270
     int
271
     ether_line(char *l, struct ether_addr *e, char *hostname);
272
 
273
DESCRIPTION
274
     Ethernet addresses are represented by the following structure:
275
 
276
           struct ether_addr {
277
                   u_int8_t  ether_addr_octet[6];
278
           };
279
 
280
     The ether_ntoa() function converts this structure into an ASCII string of
281
     the form ``xx:xx:xx:xx:xx:xx'', consisting of 6 hexadecimal numbers sepa-
282
     rated by colons.  It returns a pointer to a static buffer that is reused
283
     for each call.  The ether_aton() converts an ASCII string of the same
284
     form and to a structure containing the 6 octets of the address.  It
285
     returns a pointer to a static structure that is reused for each call.
286
 
287
     The ether_ntohost() and ether_hostton() functions interrogate the
288
     database mapping host names to Ethernet addresses, /etc/ethers.  The
289
     ether_ntohost() function looks up the given Ethernet address and writes
290
     the associated host name into the character buffer passed.  This buffer
291
     should be MAXHOSTNAMELEN characters in size.  The ether_hostton() func-
292
     tion looks up the given host name and writes the associated Ethernet
293
     address into the structure passed.  Both functions return zero if they
294
     find the requested host name or address, and -1 if not.
295
 
296
     Each call reads /etc/ethers from the beginning; if a `+' appears alone on
297
     a line in the file, then ether_hostton() will consult the ethers.byname
298
     YP map, and ether_ntohost() will consult the ethers.byaddr YP map.
299
 
300
     The ether_line() function parses a line from the /etc/ethers file and
301
     fills in the passed struct ether_addr and character buffer with the Eth-
302
     ernet address and host name on the line.  It returns zero if the line was
303
     successfully parsed and -1 if not.  The character buffer should be
304
     MAXHOSTNAMELEN characters in size.
305
 
306
FILES
307
     /etc/ethers
308
 
309
SEE ALSO
310
     ethers(5)
311
 
312
HISTORY
313
     The ether_ntoa(), ether_aton(), ether_ntohost(), ether_hostton(), and
314
     ether_line() functions were adopted from SunOS and appeared in NetBSD 0.9
315
     b.
316
 
317
BUGS
318
     The data space used by these functions is static; if future use requires
319
     the data, it should be copied before any subsequent calls to these func-
320
     tions overwrite it.
321
 
322
BSD                            December 16, 1993                           BSD
323
    
324
  
325
 
326
  
327
    getaddrinfo
328
    
329
GETADDRINFO(3)          System Library Functions Manual         GETADDRINFO(3)
330
 
331
NAME
332
     getaddrinfo, freeaddrinfo, gai_strerror - nodename-to-address translation
333
     in protocol-independent manner
334
 
335
SYNOPSIS
336
     #include <sys/types.h>
337
     #include <sys/socket.h>
338
     #include <netdb.h>
339
 
340
     int
341
     getaddrinfo(const char *nodename, const char *servname,
342
             const struct addrinfo *hints, struct addrinfo **res);
343
 
344
     void
345
     freeaddrinfo(struct addrinfo *ai);
346
 
347
     char *
348
     gai_strerror(int ecode);
349
 
350
DESCRIPTION
351
     The getaddrinfo() function is defined for protocol-independent nodename-
352
     to-address translation.  It performs the functionality of
353
     gethostbyname(3) and getservbyname(3), but in a more sophisticated man-
354
     ner.
355
 
356
     The addrinfo structure is defined as a result of including the <netdb.h>
357
     header:
358
 
359
     struct addrinfo {                                                  *
360
          int     ai_flags;     /* AI_PASSIVE, AI_CANONNAME, AI_NUMERICHOST */
361
          int     ai_family;    /* PF_xxx */
362
          int     ai_socktype;  /* SOCK_xxx */
363
          int     ai_protocol;  /* 0 or IPPROTO_xxx for IPv4 and IPv6 */
364
          size_t  ai_addrlen;   /* length of ai_addr */
365
          char   *ai_canonname; /* canonical name for nodename */
366
          struct sockaddr  *ai_addr; /* binary address */
367
          struct addrinfo  *ai_next; /* next structure in linked list */
368
     };
369
 
370
     The nodename and servname arguments are pointers to NUL-terminated
371
     strings or NULL.  One or both of these two arguments must be a non-null
372
     pointer.  In the normal client scenario, both the nodename and servname
373
     are specified.  In the normal server scenario, only the servname is spec-
374
     ified.  A non-null nodename string can be either a node name or a numeric
375
     host address string (i.e., a dotted-decimal IPv4 address or an IPv6 hex
376
     address).  A non-null servname string can be either a service name or a
377
     decimal port number.
378
 
379
     The caller can optionally pass an addrinfo structure, pointed to by the
380
     third argument, to provide hints concerning the type of socket that the
381
     caller supports.  In this hints structure all members other than
382
     ai_flags, ai_family, ai_socktype, and ai_protocol must be zero or a null
383
     pointer.  A value of PF_UNSPEC for ai_family means the caller will accept
384
     any protocol family.  A value of 0 for ai_socktype means the caller will
385
     accept any socket type.  A value of 0 for ai_protocol means the caller
386
     will accept any protocol.  For example, if the caller handles only TCP
387
     and not UDP, then the ai_socktype member of the hints structure should be
388
     set to SOCK_STREAM when getaddrinfo() is called.  If the caller handles
389
     only IPv4 and not IPv6, then the ai_family member of the hints structure
390
     should be set to PF_INET when getaddrinfo() is called.  If the third
391
     argument to getaddrinfo() is a null pointer, this is the same as if the
392
     caller had filled in an addrinfo structure initialized to zero with
393
     ai_family set to PF_UNSPEC.
394
 
395
     Upon successful return a pointer to a linked list of one or more addrinfo
396
     structures is returned through the final argument.  The caller can pro-
397
     cess each addrinfo structure in this list by following the ai_next
398
     pointer, until a null pointer is encountered.  In each returned addrinfo
399
     structure the three members ai_family, ai_socktype, and ai_protocol are
400
     the corresponding arguments for a call to the socket() function.  In each
401
     addrinfo structure the ai_addr member points to a filled-in socket
402
     address structure whose length is specified by the ai_addrlen member.
403
 
404
     If the AI_PASSIVE bit is set in the ai_flags member of the hints struc-
405
     ture, then the caller plans to use the returned socket address structure
406
     in a call to bind().  In this case, if the nodename argument is a null
407
     pointer, then the IP address portion of the socket address structure will
408
     be set to INADDR_ANY for an IPv4 address or IN6ADDR_ANY_INIT for an IPv6
409
     address.
410
 
411
     If the AI_PASSIVE bit is not set in the ai_flags member of the hints
412
     structure, then the returned socket address structure will be ready for a
413
     call to connect() (for a connection-oriented protocol) or either
414
     connect(), sendto(), or sendmsg() (for a connectionless protocol).  In
415
     this case, if the nodename argument is a null pointer, then the IP
416
     address portion of the socket address structure will be set to the loop-
417
     back address.
418
 
419
     If the AI_CANONNAME bit is set in the ai_flags member of the hints struc-
420
     ture, then upon successful return the ai_canonname member of the first
421
     addrinfo structure in the linked list will point to a NUL-terminated
422
     string containing the canonical name of the specified nodename.
423
 
424
     If the AI_NUMERICHOST bit is set in the ai_flags member of the hints
425
     structure, then a non-null nodename string must be a numeric host address
426
     string.  Otherwise an error of EAI_NONAME is returned.  This flag pre-
427
     vents any type of name resolution service (e.g., the DNS) from being
428
     called.
429
 
430
     The arguments to getaddrinfo() must sufficiently be consistent and unam-
431
     biguous.  Here are pitfall cases you may encounter:
432
 
433
     o   getaddrinfo() will raise an error if members of the hints structure
434
         are not consistent.  For example, for internet address families,
435
         getaddrinfo() will raise an error if you specify SOCK_STREAM to
436
         ai_socktype while you specify IPPROTO_UDP to ai_protocol.
437
 
438
     o   If you specify a servname which is defined only for certain
439
         ai_socktype, getaddrinfo() will raise an error because the arguments
440
         are not consistent.  For example, getaddrinfo() will raise an error
441
         if you ask for ``tftp'' service on SOCK_STREAM.
442
 
443
     o   For internet address families, if you specify servname while you set
444
         ai_socktype to SOCK_RAW, getaddrinfo() will raise an error, because
445
         service names are not defined for the internet SOCK_RAW space.
446
 
447
     o   If you specify a numeric servname, while leaving ai_socktype and
448
         ai_protocol unspecified, getaddrinfo() will raise an error.  This is
449
         because the numeric servname does not identify any socket type, and
450
         getaddrinfo() is not allowed to glob the argument in such case.
451
 
452
     All of the information returned by getaddrinfo() is dynamically allo-
453
     cated: the addrinfo structures, the socket address structures, and canon-
454
     ical node name strings pointed to by the addrinfo structures.  To return
455
     this information to the system the function freeaddrinfo() is called.
456
     The addrinfo structure pointed to by the ai argument is freed, along with
457
     any dynamic storage pointed to by the structure.  This operation is
458
     repeated until a NULL ai_next pointer is encountered.
459
 
460
     To aid applications in printing error messages based on the EAI_xxx codes
461
     returned by getaddrinfo(), gai_strerror() is defined.  The argument is
462
     one of the EAI_xxx values defined earlier and the return value points to
463
     a string describing the error.  If the argument is not one of the EAI_xxx
464
     values, the function still returns a pointer to a string whose contents
465
     indicate an unknown error.
466
 
467
   Extension for scoped IPv6 address
468
     The implementation allows experimental numeric IPv6 address notation with
469
     scope identifier.  By appending the percent character and scope identi-
470
     fier to addresses, you can fill sin6_scope_id field for addresses.  This
471
     would make management of scoped address easier, and allows cut-and-paste
472
     input of scoped address.
473
 
474
     At this moment the code supports only link-local addresses with the for-
475
     mat.  Scope identifier is hardcoded to name of hardware interface associ-
476
     ated with the link.  (such as ne0).  Example would be like
477
     ``fe80::1%ne0'', which means ``fe80::1 on the link associated with ne0
478
     interface''.
479
 
480
     The implementation is still very experimental and non-standard.  The cur-
481
     rent implementation assumes one-by-one relationship between interface and
482
     link, which is not necessarily true from the specification.
483
 
484
EXAMPLES
485
     The following code tries to connect to ``www.kame.net'' service ``http''.
486
     via stream socket.  It loops through all the addresses available, regard-
487
     less from address family.  If the destination resolves to IPv4 address,
488
     it will use AF_INET socket.  Similarly, if it resolves to IPv6, AF_INET6
489
     socket is used.  Observe that there is no hardcoded reference to particu-
490
     lar address family.  The code works even if getaddrinfo returns addresses
491
     that are not IPv4/v6.
492
 
493
           struct addrinfo hints, *res, *res0;
494
           int error;
495
           int s;
496
           const char *cause = NULL;
497
 
498
           memset(&hints, 0, sizeof(hints));
499
           hints.ai_family = PF_UNSPEC;
500
           hints.ai_socktype = SOCK_STREAM;
501
           error = getaddrinfo("www.kame.net", "http", &hints, &res0);
502
           if (error) {
503
                   errx(1, "%s", gai_strerror(error));
504
                   /*NOTREACHED*/
505
           }
506
           s = -1;
507
           for (res = res0; res; res = res->ai_next) {
508
                   s = socket(res->ai_family, res->ai_socktype,
509
                       res->ai_protocol);
510
                   if (s < 0) {
511
                           cause = "socket";
512
                           continue;
513
                   }
514
 
515
                   if (connect(s, res->ai_addr, res->ai_addrlen) < 0) {
516
                           cause = "connect";
517
                           close(s);
518
                           s = -1;
519
                           continue;
520
                   }
521
 
522
                   break;  /* okay we got one */
523
           }
524
           if (s < 0) {
525
                   err(1, cause);
526
                   /*NOTREACHED*/
527
           }
528
           freeaddrinfo(res0);
529
 
530
     The following example tries to open a wildcard listening socket onto ser-
531
     vice ``http'', for all the address families available.
532
 
533
           struct addrinfo hints, *res, *res0;
534
           int error;
535
           int s[MAXSOCK];
536
           int nsock;
537
           const char *cause = NULL;
538
 
539
           memset(&hints, 0, sizeof(hints));
540
           hints.ai_family = PF_UNSPEC;
541
           hints.ai_socktype = SOCK_STREAM;
542
           hints.ai_flags = AI_PASSIVE;
543
           error = getaddrinfo(NULL, "http", &hints, &res0);
544
           if (error) {
545
                   errx(1, "%s", gai_strerror(error));
546
                   /*NOTREACHED*/
547
           }
548
           nsock = 0;
549
           for (res = res0; res && nsock < MAXSOCK; res = res->ai_next) {
550
                   s[nsock] = socket(res->ai_family, res->ai_socktype,
551
                       res->ai_protocol);
552
                   if (s[nsock] < 0) {
553
                           cause = "socket";
554
                           continue;
555
                   }
556
 
557
                   if (bind(s[nsock], res->ai_addr, res->ai_addrlen) < 0) {
558
                           cause = "bind";
559
                           close(s[nsock]);
560
                           continue;
561
                   }
562
                   (void) listen(s[nsock], 5);
563
 
564
                   nsock++;
565
           }
566
           if (nsock == 0) {
567
                   err(1, cause);
568
                   /*NOTREACHED*/
569
           }
570
           freeaddrinfo(res0);
571
 
572
DIAGNOSTICS
573
     Error return status from getaddrinfo() is zero on success and non-zero on
574
     errors.  Non-zero error codes are defined in <netdb.h>, and as follows:
575
 
576
     EAI_ADDRFAMILY  Address family for nodename not supported.
577
     EAI_AGAIN       Temporary failure in name resolution.
578
     EAI_BADFLAGS    Invalid value for ai_flags.
579
     EAI_FAIL        Non-recoverable failure in name resolution.
580
     EAI_FAMILY      ai_family not supported.
581
     EAI_MEMORY      Memory allocation failure.
582
     EAI_NODATA      No address associated with nodename.
583
     EAI_NONAME      nodename nor servname provided, or not known.
584
     EAI_SERVICE     servname not supported for ai_socktype.
585
     EAI_SOCKTYPE    ai_socktype not supported.
586
     EAI_SYSTEM      System error returned in errno.
587
 
588
     If called with proper argument, gai_strerror() returns a pointer to a
589
     string describing the given error code.  If the argument is not one of
590
     the EAI_xxx values, the function still returns a pointer to a string
591
     whose contents indicate an unknown error.
592
 
593
SEE ALSO
594
     getnameinfo(3), gethostbyname(3), getservbyname(3), hosts(5),
595
     resolv.conf(5), services(5), hostname(7), named(8)
596
 
597
     R. Gilligan, S. Thomson, J. Bound, and W. Stevens, Basic Socket Interface
598
     Extensions for IPv6, RFC2553, March 1999.
599
 
600
     Tatsuya Jinmei and Atsushi Onoe, An Extension of Format for IPv6 Scoped
601
     Addresses, internet draft, draft-ietf-ipngwg-scopedaddr-format-02.txt,
602
     work in progress material.
603
 
604
     Craig Metz, "Protocol Independence Using the Sockets API", Proceedings of
605
     the freenix track: 2000 USENIX annual technical conference, June 2000.
606
 
607
HISTORY
608
     The implementation first appeared in WIDE Hydrangea IPv6 protocol stack
609
     kit.
610
 
611
STANDARDS
612
     The getaddrinfo() function is defined in IEEE POSIX 1003.1g draft speci-
613
     fication, and documented in ``Basic Socket Interface Extensions for
614
     IPv6'' (RFC2553).
615
 
616
BUGS
617
     The current implementation is not thread-safe.
618
 
619
     The text was shamelessly copied from RFC2553.
620
 
621
BSD                              May 25, 1995                              BSD
622
    
623
  
624
 
625
  
626
    gethostbyname
627
    
628
GETHOSTBYNAME(3)        System Library Functions Manual       GETHOSTBYNAME(3)
629
 
630
NAME
631
     gethostbyname, gethostbyname2, gethostbyaddr, gethostent, sethostent,
632
     endhostent, hstrerror, herror - get network host entry
633
 
634
SYNOPSIS
635
     #include <netdb.h>
636
     extern int h_errno;
637
 
638
     struct hostent *
639
     gethostbyname(const char *name);
640
 
641
     struct hostent *
642
     gethostbyname2(const char *name, int af);
643
 
644
     struct hostent *
645
     gethostbyaddr(const char *addr, int len, int af);
646
 
647
     struct hostent *
648
     gethostent(void);
649
 
650
     void
651
     sethostent(int stayopen);
652
 
653
     void
654
     endhostent(void);
655
 
656
     void
657
     herror(const char *string);
658
 
659
     const char *
660
     hstrerror(int err);
661
 
662
DESCRIPTION
663
     The gethostbyname() and gethostbyaddr() functions each return a pointer
664
     to an object with the following structure describing an internet host
665
     referenced by name or by address, respectively.  This structure contains
666
     either information obtained from the name server (i.e., resolver(3) and
667
     named(8)), broken-out fields from a line in /etc/hosts, or database
668
     entries supplied by the yp(8) system.  resolv.conf(5) describes how the
669
     particular database is chosen.
670
 
671
     struct  hostent {
672
             char    *h_name;        /* official name of host */
673
             char    **h_aliases;    /* alias list */
674
             int     h_addrtype;     /* host address type */
675
             int     h_length;       /* length of address */
676
             char    **h_addr_list;  /* list of addresses from name server */
677
     };
678
     #define h_addr  h_addr_list[0]  /* address, for backward compatibility */
679
 
680
     The members of this structure are:
681
 
682
     h_name       Official name of the host.
683
 
684
     h_aliases    A zero-terminated array of alternate names for the host.
685
 
686
     h_addrtype   The type of address being returned.
687
 
688
     h_length     The length, in bytes, of the address.
689
 
690
     h_addr_list  A zero-terminated array of network addresses for the host.
691
                  Host addresses are returned in network byte order.
692
 
693
     h_addr       The first address in h_addr_list; this is for backward com-
694
                  patibility.
695
 
696
     The function gethostbyname() will search for the named host in the cur-
697
     rent domain and its parents using the search lookup semantics detailed in
698
     resolv.conf(5) and hostname(7).
699
 
700
     gethostbyname2() is an advanced form of gethostbyname() which allows
701
     lookups in address families other than AF_INET, for example AF_INET6.
702
 
703
     The gethostbyaddr() function will search for the specified address of
704
     length len in the address family af.  The only address family currently
705
     supported is AF_INET.
706
 
707
     The sethostent() function may be used to request the use of a connected
708
     TCP socket for queries.  If the stayopen flag is non-zero, this sets the
709
     option to send all queries to the name server using TCP and to retain the
710
     connection after each call to gethostbyname() or gethostbyaddr().  Other-
711
     wise, queries are performed using UDP datagrams.
712
 
713
     The endhostent() function closes the TCP connection.
714
 
715
     The herror() function prints an error message describing the failure.  If
716
     its argument string is non-null, it is prepended to the message string
717
     and separated from it by a colon (`:') and a space.  The error message is
718
     printed with a trailing newline.  The contents of the error message is
719
     the same as that returned by hstrerror() with argument h_errno.
720
 
721
FILES
722
     /etc/hosts
723
     /etc/resolv.conf
724
 
725
DIAGNOSTICS
726
     Error return status from gethostbyname(), gethostbyname2(), and
727
     gethostbyaddr() is indicated by return of a null pointer.  The external
728
     integer h_errno may then be checked to see whether this is a temporary
729
     failure or an invalid or unknown host.
730
 
731
     The variable h_errno can have the following values:
732
 
733
     HOST_NOT_FOUND  No such host is known.
734
 
735
     TRY_AGAIN       This is usually a temporary error and means that the
736
                     local server did not receive a response from an authori-
737
                     tative server.  A retry at some later time may succeed.
738
 
739
     NO_RECOVERY     Some unexpected server failure was encountered.  This is
740
                     a non-recoverable error.
741
 
742
     NO_DATA         The requested name is valid but does not have an IP
743
                     address; this is not a temporary error.  This means that
744
                     the name is known to the name server but there is no
745
                     address associated with this name.  Another type of
746
                     request to the name server using this domain name will
747
                     result in an answer; for example, a mail-forwarder may be
748
                     registered for this domain.
749
 
750
SEE ALSO
751
     resolver(3), getaddrinfo(3), getnameinfo(3), hosts(5), resolv.conf(5),
752
     hostname(7), named(8)
753
 
754
CAVEAT
755
     If the search routines in resolv.conf(5) decide to read the /etc/hosts
756
     file, gethostent() and other functions will read the next line of the
757
     file, re-opening the file if necessary.
758
 
759
     The sethostent() function opens and/or rewinds the file /etc/hosts.  If
760
     the stayopen argument is non-zero, the file will not be closed after each
761
     call to gethostbyname(), gethostbyname2(), or gethostbyaddr().
762
 
763
     The endhostent() function closes the file.
764
 
765
HISTORY
766
     The herror() function appeared in 4.3BSD.  The endhostent(),
767
     gethostbyaddr(), gethostbyname(), gethostent(), and sethostent() func-
768
     tions appeared in 4.2BSD.
769
 
770
BUGS
771
     These functions use static data storage; if the data is needed for future
772
     use, it should be copied before any subsequent calls overwrite it.  Only
773
     the Internet address formats are currently understood.
774
 
775
     YP does not support any address families other than AF_INET and uses the
776
     traditional database format.
777
 
778
BSD                             March 13, 1997                             BSD
779
    
780
  
781
 
782
  
783
    getifaddrs
784
    
785
GETIFADDRS(3)           System Library Functions Manual          GETIFADDRS(3)
786
 
787
NAME
788
     getifaddrs - get interface addresses
789
 
790
SYNOPSIS
791
     #include <sys/types.h>
792
     #include <sys/socket.h>
793
     #include <ifaddrs.h>
794
 
795
     int
796
     getifaddrs(struct ifaddrs **ifap);
797
 
798
     void
799
     freeifaddrs(struct ifaddrs *ifap);
800
 
801
DESCRIPTION
802
     The getifaddrs() function stores a reference to a linked list of the net-
803
     work interfaces on the local machine in the memory referenced by ifap.
804
     The list consists of ifaddrs structures, as defined in the include file
805
     <ifaddrs.h>.  The ifaddrs structure contains at least the following
806
     entries:
807
 
808
         struct ifaddrs   *ifa_next;         /* Pointer to next struct */
809
         char             *ifa_name;         /* Interface name */
810
         u_int             ifa_flags;        /* Interface flags */
811
         struct sockaddr  *ifa_addr;         /* Interface address */
812
         struct sockaddr  *ifa_netmask;      /* Interface netmask */
813
         struct sockaddr  *ifa_broadaddr;    /* Interface broadcast address */
814
         struct sockaddr  *ifa_dstaddr;      /* P2P interface destination */
815
         void             *ifa_data;         /* Address specific data */
816
 
817
     ifa_next
818
             Contains a pointer to the next structure on the list.  This field
819
             is set to NULL in last structure on the list.
820
 
821
     ifa_name
822
             Contains the interface name.
823
 
824
     ifa_flags
825
             Contains the interface flags, as set by ifconfig(8).
826
 
827
     ifa_addr
828
             References either the address of the interface or the link level
829
             address of the interface, if one exists, otherwise it is NULL.
830
             (The sa_family field of the ifa_addr field should be consulted to
831
             determine the format of the ifa_addr address.)
832
 
833
     ifa_netmask
834
             References the netmask associated with ifa_addr, if one is set,
835
             otherwise it is NULL.
836
 
837
     ifa_broadaddr
838
             This field, which should only be referenced for non-P2P inter-
839
             faces, references the broadcast address associated with ifa_addr,
840
             if one exists, otherwise it is NULL.
841
 
842
     ifa_dstaddr
843
             References the destination address on a P2P interface, if one
844
             exists, otherwise it is NULL.
845
 
846
     ifa_data
847
             References address family specific data.  For AF_LINK addresses
848
             it contains a pointer to the struct if_data (as defined in
849
             include file <net/if.h>) which contains various interface
850
             attributes and statistics.  For all other address families, it
851
             contains a pointer to the struct ifa_data (as defined in include
852
             file <net/if.h>) which contains per-address interface statistics.
853
 
854
     The data returned by getifaddrs() is dynamically allocated and should be
855
     freed using freeifaddrs() when no longer needed.
856
 
857
RETURN VALUES
858
     Upon successful completion, a value of 0 is returned.  Otherwise, a value
859
     of -1 is returned and errno is set to indicate the error.
860
 
861
ERRORS
862
     The getifaddrs() may fail and set errno for any of the errors specified
863
     for the library routines ioctl(2), socket(2), malloc(3), or sysctl(3).
864
 
865
BUGS
866
     If both <net/if.h> and <ifaddrs.h> are being included, <net/if.h> must be
867
     included before <ifaddrs.h>.
868
 
869
SEE ALSO
870
     ioctl(2), socket(2), sysctl(3), networking(4), ifconfig(8)
871
 
872
HISTORY
873
     The getifaddrs() function first appeared in BSDI BSD/OS.  The function is
874
     supplied on OpenBSD since OpenBSD 2.7.
875
 
876
BSD                            February 24, 2003                           BSD
877
    
878
  
879
 
880
  
881
    getnameinfo
882
    
883
GETNAMEINFO(3)          System Library Functions Manual         GETNAMEINFO(3)
884
 
885
NAME
886
     getnameinfo - address-to-nodename translation in protocol-independent
887
     manner
888
 
889
SYNOPSIS
890
     #include <sys/types.h>
891
     #include <sys/socket.h>
892
     #include <netdb.h>
893
 
894
     int
895
     getnameinfo(const struct sockaddr *sa, socklen_t salen, char *host,
896
             size_t hostlen, char *serv, size_t servlen, int flags);
897
 
898
DESCRIPTION
899
     The getnameinfo() function is defined for protocol-independent address-
900
     to-nodename translation.  Its functionality is a reverse conversion of
901
     getaddrinfo(3), and implements similar functionality with
902
     gethostbyaddr(3) and getservbyport(3) in more sophisticated manner.
903
 
904
     This function looks up an IP address and port number provided by the
905
     caller in the DNS and system-specific database, and returns text strings
906
     for both in buffers provided by the caller.  The function indicates suc-
907
     cessful completion by a zero return value; a non-zero return value indi-
908
     cates failure.
909
 
910
     The first argument, sa, points to either a sockaddr_in structure (for
911
     IPv4) or a sockaddr_in6 structure (for IPv6) that holds the IP address
912
     and port number.  The salen argument gives the length of the sockaddr_in
913
     or sockaddr_in6 structure.
914
 
915
     The function returns the nodename associated with the IP address in the
916
     buffer pointed to by the host argument.  The caller provides the size of
917
     this buffer via the hostlen argument.  The service name associated with
918
     the port number is returned in the buffer pointed to by serv, and the
919
     servlen argument gives the length of this buffer.  The caller specifies
920
     not to return either string by providing a zero value for the hostlen or
921
     servlen arguments.  Otherwise, the caller must provide buffers large
922
     enough to hold the nodename and the service name, including the terminat-
923
     ing null characters.
924
 
925
     Unfortunately most systems do not provide constants that specify the max-
926
     imum size of either a fully-qualified domain name or a service name.
927
     Therefore to aid the application in allocating buffers for these two
928
     returned strings the following constants are defined in <netdb.h>:
929
 
930
     #define NI_MAXHOST    MAXHOSTNAMELEN
931
     #define NI_MAXSERV    32
932
 
933
     The first value is actually defined as the constant MAXDNAME in recent
934
     versions of BIND's <arpa/nameser.h> header (older versions of BIND define
935
     this constant to be 256) and the second is a guess based on the services
936
     listed in the current Assigned Numbers RFC.
937
 
938
     The final argument is a flag that changes the default actions of this
939
     function.  By default the fully-qualified domain name (FQDN) for the host
940
     is looked up in the DNS and returned.  If the flag bit NI_NOFQDN is set,
941
     only the nodename portion of the FQDN is returned for local hosts.
942
 
943
     If the flag bit NI_NUMERICHOST is set, or if the host's name cannot be
944
     located in the DNS, the numeric form of the host's address is returned
945
     instead of its name (e.g., by calling inet_ntop() instead of
946
     gethostbyaddr()).  If the flag bit NI_NAMEREQD is set, an error is
947
     returned if the host's name cannot be located in the DNS.
948
 
949
     If the flag bit NI_NUMERICSERV is set, the numeric form of the service
950
     address is returned (e.g., its port number) instead of its name.  The two
951
     NI_NUMERICxxx flags are required to support the -n flag that many com-
952
     mands provide.
953
 
954
     A fifth flag bit, NI_DGRAM, specifies that the service is a datagram ser-
955
     vice, and causes getservbyport() to be called with a second argument of
956
     "udp" instead of its default of "tcp".  This is required for the few
957
     ports (512-514) that have different services for UDP and TCP.
958
 
959
     These NI_xxx flags are defined in <netdb.h>.
960
 
961
   Extension for scoped IPv6 address
962
     The implementation allows experimental numeric IPv6 address notation with
963
     scope identifier.  IPv6 link-local address will appear as string like
964
     ``fe80::1%ne0'', if NI_WITHSCOPEID bit is enabled in flags argument.
965
     Refer to getaddrinfo(3) for the notation.
966
 
967
EXAMPLES
968
     The following code tries to get numeric hostname, and service name, for
969
     given socket address.  Observe that there is no hardcoded reference to
970
     particular address family.
971
 
972
           struct sockaddr *sa;    /* input */
973
           char hbuf[NI_MAXHOST], sbuf[NI_MAXSERV];
974
 
975
           if (getnameinfo(sa, sa->sa_len, hbuf, sizeof(hbuf), sbuf,
976
               sizeof(sbuf), NI_NUMERICHOST | NI_NUMERICSERV)) {
977
                   errx(1, "could not get numeric hostname");
978
                   /*NOTREACHED*/
979
           }
980
           printf("host=%s, serv=%s\n", hbuf, sbuf);
981
 
982
     The following version checks if the socket address has reverse address
983
     mapping.
984
 
985
           struct sockaddr *sa;    /* input */
986
           char hbuf[NI_MAXHOST];
987
 
988
           if (getnameinfo(sa, sa->sa_len, hbuf, sizeof(hbuf), NULL, 0,
989
               NI_NAMEREQD)) {
990
                   errx(1, "could not resolve hostname");
991
                   /*NOTREACHED*/
992
           }
993
           printf("host=%s\n", hbuf);
994
 
995
DIAGNOSTICS
996
     The function indicates successful completion by a zero return value; a
997
     non-zero return value indicates failure.  Error codes are as below:
998
 
999
     EAI_AGAIN          The name could not be resolved at this time.  Future
1000
                        attempts may succeed.
1001
 
1002
     EAI_BADFLAGS       The flags had an invalid value.
1003
 
1004
     EAI_FAIL           A non-recoverable error occurred.
1005
 
1006
     EAI_FAMILY         The address family was not recognized or the address
1007
                        length was invalid for the specified family.
1008
 
1009
     EAI_MEMORY         There was a memory allocation failure.
1010
 
1011
     EAI_NONAME         The name does not resolve for the supplied parameters.
1012
                        NI_NAMEREQD is set and the host's name cannot be
1013
                        located, or both nodename and servname were null.
1014
 
1015
     EAI_SYSTEM         A system error occurred.  The error code can be found
1016
                        in errno.
1017
 
1018
SEE ALSO
1019
     getaddrinfo(3), gethostbyaddr(3), getservbyport(3), hosts(5),
1020
     resolv.conf(5), services(5), hostname(7), named(8)
1021
 
1022
     R. Gilligan, S. Thomson, J. Bound, and W. Stevens, Basic Socket Interface
1023
     Extensions for IPv6, RFC2553, March 1999.
1024
 
1025
     Tatsuya Jinmei and Atsushi Onoe, An Extension of Format for IPv6 Scoped
1026
     Addresses, internet draft, draft-ietf-ipngwg-scopedaddr-format-02.txt,
1027
     work in progress material.
1028
 
1029
     Craig Metz, "Protocol Independence Using the Sockets API", Proceedings of
1030
     the freenix track: 2000 USENIX annual technical conference, June 2000.
1031
 
1032
HISTORY
1033
     The implementation first appeared in WIDE Hydrangea IPv6 protocol stack
1034
     kit.
1035
 
1036
STANDARDS
1037
     The getaddrinfo() function is defined IEEE POSIX 1003.1g draft specifica-
1038
     tion, and documented in ``Basic Socket Interface Extensions for IPv6''
1039
     (RFC2553).
1040
 
1041
BUGS
1042
     The current implementation is not thread-safe.
1043
 
1044
     The text was shamelessly copied from RFC2553.
1045
 
1046
     OpenBSD intentionally uses different NI_MAXHOST value from what RFC2553
1047
     suggests, to avoid buffer length handling mistakes.
1048
 
1049
BSD                              May 25, 1995                              BSD
1050
    
1051
  
1052
 
1053
  
1054
    getnetent
1055
    
1056
GETNETENT(3)            System Library Functions Manual           GETNETENT(3)
1057
 
1058
NAME
1059
     getnetent, getnetbyaddr, getnetbyname, setnetent, endnetent - get network
1060
     entry
1061
 
1062
SYNOPSIS
1063
     #include <netdb.h>
1064
 
1065
     struct netent *
1066
     getnetent(void);
1067
 
1068
     struct netent *
1069
     getnetbyname(char *name);
1070
 
1071
     struct netent *
1072
     getnetbyaddr(in_addr_t net, int type);
1073
 
1074
     void
1075
     setnetent(int stayopen);
1076
 
1077
     void
1078
     endnetent(void);
1079
 
1080
DESCRIPTION
1081
     The getnetent(), getnetbyname(), and getnetbyaddr() functions each return
1082
     a pointer to an object with the following structure containing the bro-
1083
     ken-out fields of a line in the network database, /etc/networks.
1084
 
1085
           struct  netent {
1086
                   char            *n_name;        /* official name of net */
1087
                   char            **n_aliases;    /* alias list */
1088
                   int             n_addrtype;     /* net number type */
1089
                   in_addr_t       n_net;          /* net number */
1090
           };
1091
 
1092
     The members of this structure are:
1093
 
1094
     n_name      The official name of the network.
1095
 
1096
     n_aliases   A zero-terminated list of alternate names for the network.
1097
 
1098
     n_addrtype  The type of the network number returned; currently only
1099
                 AF_INET.
1100
 
1101
     n_net       The network number.  Network numbers are returned in machine
1102
                 byte order.
1103
 
1104
     The getnetent() function reads the next line of the file, opening the
1105
     file if necessary.
1106
 
1107
     The setnetent() function opens and rewinds the file.  If the stayopen
1108
     flag is non-zero, the net database will not be closed after each call to
1109
     getnetbyname() or getnetbyaddr().
1110
 
1111
     The endnetent() function closes the file.
1112
 
1113
     The getnetbyname() and getnetbyaddr() functions search the domain name
1114
     server if the system is configured to use one.  If the search fails, or
1115
     no name server is configured, they sequentially search from the beginning
1116
     of the file until a matching net name or net address and type is found,
1117
     or until EOF is encountered.  Network numbers are supplied in host order.
1118
 
1119
FILES
1120
     /etc/networks
1121
 
1122
DIAGNOSTICS
1123
     Null pointer (0) returned on EOF or error.
1124
 
1125
SEE ALSO
1126
     resolver(3), networks(5)
1127
 
1128
HISTORY
1129
     The getnetent(), getnetbyaddr(), getnetbyname(), setnetent(), and
1130
     endnetent() functions appeared in 4.2BSD.
1131
 
1132
BUGS
1133
     The data space used by these functions is static; if future use requires
1134
     the data, it should be copied before any subsequent calls to these func-
1135
     tions overwrite it.  Only Internet network numbers are currently under-
1136
     stood.  Expecting network numbers to fit in no more than 32 bits is
1137
     naive.
1138
 
1139
BSD                             March 13, 1997                             BSD
1140
    
1141
  
1142
 
1143
  
1144
    getprotoent
1145
    
1146
GETPROTOENT(3)          System Library Functions Manual         GETPROTOENT(3)
1147
 
1148
NAME
1149
     getprotoent, getprotobynumber, getprotobyname, setprotoent, endprotoent -
1150
     get protocol entry
1151
 
1152
SYNOPSIS
1153
     #include <netdb.h>
1154
 
1155
     struct protoent *
1156
     getprotoent(void);
1157
 
1158
     struct protoent *
1159
     getprotobyname(char *name);
1160
 
1161
     struct protoent *
1162
     getprotobynumber(int proto);
1163
 
1164
     void
1165
     setprotoent(int stayopen);
1166
 
1167
     void
1168
     endprotoent(void);
1169
 
1170
DESCRIPTION
1171
     The getprotoent(), getprotobyname(), and getprotobynumber() functions
1172
     each return a pointer to an object with the following structure contain-
1173
     ing the broken-out fields of a line in the network protocol database,
1174
     /etc/protocols.
1175
 
1176
 
1177
           struct  protoent {
1178
                   char    *p_name;        /* official name of protocol */
1179
                   char    **p_aliases;    /* alias list */
1180
                   int     p_proto;        /* protocol number */
1181
           };
1182
 
1183
     The members of this structure are:
1184
 
1185
     p_name     The official name of the protocol.
1186
 
1187
     p_aliases  A zero-terminated list of alternate names for the protocol.
1188
 
1189
     p_proto    The protocol number.
1190
 
1191
     The getprotoent() function reads the next line of the file, opening the
1192
     file if necessary.
1193
 
1194
     The setprotoent() function opens and rewinds the file.  If the stayopen
1195
     flag is non-zero, the net database will not be closed after each call to
1196
     getprotobyname() or getprotobynumber().
1197
 
1198
     The endprotoent() function closes the file.
1199
 
1200
     The getprotobyname() and getprotobynumber() functions sequentially search
1201
     from the beginning of the file until a matching protocol name or protocol
1202
     number is found, or until EOF is encountered.
1203
 
1204
RETURN VALUES
1205
     Null pointer (0) returned on EOF or error.
1206
 
1207
FILES
1208
     /etc/protocols
1209
 
1210
SEE ALSO
1211
     protocols(5)
1212
 
1213
HISTORY
1214
     The getprotoent(), getprotobynumber(), getprotobyname(), setprotoent(),
1215
     and endprotoent() functions appeared in 4.2BSD.
1216
 
1217
BUGS
1218
     These functions use a static data space; if the data is needed for future
1219
     use, it should be copied before any subsequent calls overwrite it.  Only
1220
     the Internet protocols are currently understood.
1221
 
1222
BSD                              June 4, 1993                              BSD
1223
    
1224
  
1225
 
1226
  
1227
    getrrsetbyname
1228
    
1229
GETRRSETBYNAME(3)       System Library Functions Manual      GETRRSETBYNAME(3)
1230
 
1231
NAME
1232
     getrrsetbyname - retrieve DNS records
1233
 
1234
SYNOPSIS
1235
     #include <netdb.h>
1236
 
1237
     int
1238
     getrrsetbyname(const char *hostname, unsigned int rdclass,
1239
             unsigned int rdtype, unsigned int flags, struct rrsetinfo **res);
1240
 
1241
     int
1242
     freerrset(struct rrsetinfo **rrset);
1243
 
1244
DESCRIPTION
1245
     getrrsetbyname() gets a set of resource records associated with a
1246
     hostname, class and type.  hostname is a pointer a to null-terminated
1247
     string.  The flags field is currently unused and must be zero.
1248
 
1249
     After a successful call to getrrsetbyname(), *res is a pointer to an
1250
     rrsetinfo structure, containing a list of one or more rdatainfo struc-
1251
     tures containing resource records and potentially another list of
1252
     rdatainfo structures containing SIG resource records associated with
1253
     those records.  The members rri_rdclass and rri_rdtype are copied from
1254
     the parameters.  rri_ttl and rri_name are properties of the obtained
1255
     rrset.  The resource records contained in rri_rdatas and rri_sigs are in
1256
     uncompressed DNS wire format.  Properties of the rdataset are represented
1257
     in the rri_flags bitfield. If the RRSET_VALIDATED bit is set, the data
1258
     has been DNSSEC validated and the signatures verified.
1259
 
1260
     The following structures are used:
1261
 
1262
     struct  rdatainfo {
1263
             unsigned int            rdi_length;     /* length of data */
1264
             unsigned char           *rdi_data;      /* record data */
1265
     };
1266
 
1267
     struct  rrsetinfo {
1268
             unsigned int            rri_flags;      /* RRSET_VALIDATED ... */
1269
             unsigned int            rri_rdclass;    /* class number */
1270
             unsigned int            rri_rdtype;     /* RR type number */
1271
             unsigned int            rri_ttl;        /* time to live */
1272
             unsigned int            rri_nrdatas;    /* size of rdatas array */
1273
             unsigned int            rri_nsigs;      /* size of sigs array */
1274
             char                    *rri_name;      /* canonical name */
1275
             struct rdatainfo        *rri_rdatas;    /* individual records */
1276
             struct rdatainfo        *rri_sigs;      /* individual signatures */
1277
     };
1278
 
1279
     All of the information returned by getrrsetbyname() is dynamically allo-
1280
     cated: the rrsetinfo and rdatainfo structures, and the canonical host
1281
     name strings pointed to by the rrsetinfostructure. Memory allocated for
1282
     the dynamically allocated structures created by a successful call to
1283
     getrrsetbyname() is released by freerrset().  rrset is a pointer to a
1284
     struct rrset created by a call to getrrsetbyname().
1285
 
1286
     If the EDNS0 option is activated in resolv.conf(3), getrrsetbyname() will
1287
     request DNSSEC authentication using the EDNS0 DNSSEC OK (DO) bit.
1288
 
1289
RETURN VALUES
1290
     getrrsetbyname() returns zero on success, and one of the following error
1291
     codes if an error occurred:
1292
 
1293
     ERRSET_NONAME    the name does not exist
1294
     ERRSET_NODATA    the name exists, but does not have data of the desired
1295
                      type
1296
     ERRSET_NOMEMORY  memory could not be allocated
1297
     ERRSET_INVAL     a parameter is invalid
1298
     ERRSET_FAIL      other failure
1299
 
1300
SEE ALSO
1301
     resolver(3), resolv.conf(5), named(8)
1302
 
1303
AUTHORS
1304
     Jakob Schlyter <jakob@openbsd.org>
1305
 
1306
HISTORY
1307
     getrrsetbyname() first appeared in OpenBSD 3.0.  The API first appeared
1308
     in ISC BIND version 9.
1309
 
1310
BUGS
1311
     The data in *rdi_data should be returned in uncompressed wire format.
1312
     Currently, the data is in compressed format and the caller can't uncom-
1313
     press since it doesn't have the full message.
1314
 
1315
CAVEATS
1316
     The RRSET_VALIDATED flag in rri_flags is set if the AD (autenticated
1317
     data) bit in the DNS answer is set. This flag should not be trusted
1318
     unless the transport between the nameserver and the resolver is secure
1319
     (e.g. IPsec, trusted network, loopback communication).
1320
 
1321
BSD                              Oct 18, 2000                              BSD
1322
    
1323
  
1324
 
1325
  
1326
    getservent
1327
    
1328
GETSERVENT(3)           System Library Functions Manual          GETSERVENT(3)
1329
 
1330
NAME
1331
     getservent, getservbyport, getservbyname, setservent, endservent - get
1332
     service entry
1333
 
1334
SYNOPSIS
1335
     #include <netdb.h>
1336
 
1337
     struct servent *
1338
     getservent(void);
1339
 
1340
     struct servent *
1341
     getservbyname(char *name, char *proto);
1342
 
1343
     struct servent *
1344
     getservbyport(int port, char *proto);
1345
 
1346
     void
1347
     setservent(int stayopen);
1348
 
1349
     void
1350
     endservent(void);
1351
 
1352
DESCRIPTION
1353
     The getservent(), getservbyname(), and getservbyport() functions each
1354
     return a pointer to an object with the following structure containing the
1355
     broken-out fields of a line in the network services database,
1356
     /etc/services.
1357
 
1358
           struct  servent {
1359
                   char    *s_name;        /* official name of service */
1360
                   char    **s_aliases;    /* alias list */
1361
                   int     s_port;         /* port service resides at */
1362
                   char    *s_proto;       /* protocol to use */
1363
           };
1364
 
1365
     The members of this structure are:
1366
 
1367
     s_name     The official name of the service.
1368
 
1369
     s_aliases  A zero-terminated list of alternate names for the service.
1370
 
1371
     s_port     The port number at which the service resides.  Port numbers
1372
                are returned in network byte order.
1373
 
1374
     s_proto    The name of the protocol to use when contacting the service.
1375
 
1376
     The getservent() function reads the next line of the file, opening the
1377
     file if necessary.
1378
 
1379
     The setservent() function opens and rewinds the file.  If the stayopen
1380
     flag is non-zero, the net database will not be closed after each call to
1381
     getservbyname() or getservbyport().
1382
 
1383
     The endservent() function closes the file.
1384
 
1385
     The getservbyname() and getservbyport() functions sequentially search
1386
     from the beginning of the file until a matching protocol name or port
1387
     number (specified in network byte order) is found, or until EOF is
1388
     encountered.  If a protocol name is also supplied (non-null), searches
1389
     must also match the protocol.
1390
 
1391
FILES
1392
     /etc/services
1393
 
1394
DIAGNOSTICS
1395
     Null pointer (0) returned on EOF or error.
1396
 
1397
SEE ALSO
1398
     getprotoent(3), services(5)
1399
 
1400
HISTORY
1401
     The getservent(), getservbyport(), getservbyname(), setservent(), and
1402
     endservent() functions appeared in 4.2BSD.
1403
 
1404
BUGS
1405
     These functions use static data storage; if the data is needed for future
1406
     use, it should be copied before any subsequent calls overwrite it.
1407
     Expecting port numbers to fit in a 32-bit quantity is probably naive.
1408
 
1409
BSD                            January 12, 1994                            BSD
1410
    
1411
  
1412
 
1413
  
1414
    if_nametoindex
1415
    
1416
IF_NAMETOINDEX(3)       System Library Functions Manual      IF_NAMETOINDEX(3)
1417
 
1418
NAME
1419
     if_nametoindex, if_indextoname, if_nameindex, if_freenameindex - convert
1420
     interface index to name, and vice versa
1421
 
1422
SYNOPSIS
1423
     #include <net/if.h>
1424
 
1425
     unsigned int
1426
     if_nametoindex(const char *ifname);
1427
 
1428
     char *
1429
     if_indextoname(unsigned int ifindex, char *ifname);
1430
 
1431
     struct if_nameindex *
1432
     if_nameindex(void);
1433
 
1434
     void
1435
     if_freenameindex(struct if_nameindex *ptr);
1436
 
1437
DESCRIPTION
1438
     These functions map interface indexes to interface names (such as
1439
     ``lo0''), and vice versa.
1440
 
1441
     The if_nametoindex() function converts an interface name specified by the
1442
     ifname argument to an interface index (positive integer value).  If the
1443
     specified interface does not exist, 0 will be returned.
1444
 
1445
     if_indextoname() converts an interface index specified by the ifindex
1446
     argument to an interface name.  The ifname argument must point to a
1447
     buffer of at least IF_NAMESIZE bytes into which the interface name corre-
1448
     sponding to the specified index is returned.  (IF_NAMESIZE is also
1449
     defined in <net/if.h> and its value includes a terminating null byte at
1450
     the end of the interface name.)  This pointer is also the return value of
1451
     the function.  If there is no interface corresponding to the specified
1452
     index, NULL is returned.
1453
 
1454
     if_nameindex() returns an array of if_nameindex structures.
1455
     if_nametoindex is also defined in <net/if.h>, and is as follows:
1456
 
1457
     struct if_nameindex {
1458
         unsigned int   if_index;  /* 1, 2, ... */
1459
         char          *if_name;   /* null terminated name: "le0", ... */
1460
     };
1461
 
1462
     The end of the array of structures is indicated by a structure with an
1463
     if_index of 0 and an if_name of NULL.  The function returns a null
1464
     pointer on error.  The memory used for this array of structures along
1465
     with the interface names pointed to by the if_name members is obtained
1466
     dynamically.  This memory is freed by the if_freenameindex() function.
1467
 
1468
     if_freenameindex() takes a pointer that was returned by if_nameindex() as
1469
     argument (ptr), and it reclaims the region allocated.
1470
 
1471
DIAGNOSTICS
1472
     if_nametoindex() returns 0 on error, positive integer on success.
1473
     if_indextoname() and if_nameindex() return NULL on errors.
1474
 
1475
SEE ALSO
1476
     R. Gilligan, S.  Thomson, J. Bound, and W. Stevens, ``Basic Socket Inter-
1477
     face Extensions for IPv6,'' RFC2553, March 1999.
1478
 
1479
STANDARDS
1480
     These functions are defined in ``Basic Socket Interface Extensions for
1481
     IPv6'' (RFC2533).
1482
 
1483
BSD                              May 21, 1998                              BSD
1484
    
1485
  
1486
 
1487
  
1488
    inet
1489
    
1490
INET(3)                 System Library Functions Manual                INET(3)
1491
 
1492
NAME
1493
     inet_addr, inet_aton, inet_lnaof, inet_makeaddr, inet_netof,
1494
     inet_network, inet_ntoa, inet_ntop, inet_pton - Internet address manipu-
1495
     lation routines
1496
 
1497
SYNOPSIS
1498
     #include <sys/socket.h>
1499
     #include <netinet/in.h>
1500
     #include <arpa/inet.h>
1501
 
1502
     in_addr_t
1503
     inet_addr(const char *cp);
1504
 
1505
     int
1506
     inet_aton(const char *cp, struct in_addr *addr);
1507
 
1508
     in_addr_t
1509
     inet_lnaof(struct in_addr in);
1510
 
1511
     struct in_addr
1512
     inet_makeaddr(unsigned long net, unsigned long lna);
1513
 
1514
     in_addr_t
1515
     inet_netof(struct in_addr in);
1516
 
1517
     in_addr_t
1518
     inet_network(const char *cp);
1519
 
1520
     char *
1521
     inet_ntoa(struct in_addr in);
1522
 
1523
     const char *
1524
     inet_ntop(int af, const void *src, char *dst, size_t size);
1525
 
1526
     int
1527
     inet_pton(int af, const char *src, void *dst);
1528
 
1529
DESCRIPTION
1530
     The routines inet_aton(), inet_addr() and inet_network() interpret char-
1531
     acter strings representing numbers expressed in the Internet standard `.'
1532
     notation.  The inet_pton() function converts a presentation format
1533
     address (that is, printable form as held in a character string) to net-
1534
     work format (usually a struct in_addr or some other internal binary rep-
1535
     resentation, in network byte order).  It returns 1 if the address was
1536
     valid for the specified address family, or 0 if the address wasn't
1537
     parseable in the specified address family, or -1 if some system error
1538
     occurred (in which case errno will have been set).  This function is
1539
     presently valid for AF_INET and AF_INET6.  The inet_aton() routine inter-
1540
     prets the specified character string as an Internet address, placing the
1541
     address into the structure provided.  It returns 1 if the string was suc-
1542
     cessfully interpreted, or 0 if the string was invalid.  The inet_addr()
1543
     and inet_network() functions return numbers suitable for use as Internet
1544
     addresses and Internet network numbers, respectively.
1545
 
1546
     The function inet_ntop() converts an address from network format (usually
1547
     a struct in_addr or some other binary form, in network byte order) to
1548
     presentation format (suitable for external display purposes).  It returns
1549
     NULL if a system error occurs (in which case, errno will have been set),
1550
     or it returns a pointer to the destination string.  The routine
1551
     inet_ntoa() takes an Internet address and returns an ASCII string repre-
1552
     senting the address in `.' notation.  The routine inet_makeaddr() takes
1553
     an Internet network number and a local network address and constructs an
1554
     Internet address from it.  The routines inet_netof() and inet_lnaof()
1555
     break apart Internet host addresses, returning the network number and
1556
     local network address part, respectively.
1557
 
1558
     All Internet addresses are returned in network order (bytes ordered from
1559
     left to right).  All network numbers and local address parts are returned
1560
     as machine format integer values.
1561
 
1562
INTERNET ADDRESSES (IP VERSION 4)
1563
     Values specified using the `.' notation take one of the following forms:
1564
 
1565
           a.b.c.d
1566
           a.b.c
1567
           a.b
1568
           a
1569
 
1570
     When four parts are specified, each is interpreted as a byte of data and
1571
     assigned, from left to right, to the four bytes of an Internet address.
1572
     Note that when an Internet address is viewed as a 32-bit integer quantity
1573
     on a system that uses little-endian byte order (such as the Intel 386,
1574
     486 and Pentium processors) the bytes referred to above appear as
1575
     ``d.c.b.a''.  That is, little-endian bytes are ordered from right to
1576
     left.
1577
 
1578
     When a three part address is specified, the last part is interpreted as a
1579
     16-bit quantity and placed in the rightmost two bytes of the network
1580
     address.  This makes the three part address format convenient for speci-
1581
     fying Class B network addresses as ``128.net.host''.
1582
 
1583
     When a two part address is supplied, the last part is interpreted as a
1584
     24-bit quantity and placed in the rightmost three bytes of the network
1585
     address.  This makes the two part address format convenient for specify-
1586
     ing Class A network addresses as ``net.host''.
1587
 
1588
     When only one part is given, the value is stored directly in the network
1589
     address without any byte rearrangement.
1590
 
1591
     All numbers supplied as ``parts'' in a `.' notation may be decimal,
1592
     octal, or hexadecimal, as specified in the C language (i.e., a leading 0x
1593
     or 0X implies hexadecimal; otherwise, a leading 0 implies octal; other-
1594
     wise, the number is interpreted as decimal).
1595
 
1596
INTERNET ADDRESSES (IP VERSION 6)
1597
     In order to support scoped IPv6 addresses, getaddrinfo(3) and
1598
     getnameinfo(3) are recommended rather than the functions presented here.
1599
 
1600
     The presentation format of an IPv6 address is given in [RFC1884 2.2]:
1601
 
1602
     There are three conventional forms for representing IPv6 addresses as
1603
     text strings:
1604
 
1605
     1.   The preferred form is x:x:x:x:x:x:x:x, where the 'x's are the hex-
1606
          adecimal values of the eight 16-bit pieces of the address.  Exam-
1607
          ples:
1608
 
1609
                FEDC:BA98:7654:3210:FEDC:BA98:7654:3210
1610
                1080:0:0:0:8:800:200C:417A
1611
 
1612
          Note that it is not necessary to write the leading zeros in an indi-
1613
          vidual field, but there must be at least one numeral in every field
1614
          (except for the case described in 2.).
1615
 
1616
     2.   Due to the method of allocating certain styles of IPv6 addresses, it
1617
          will be common for addresses to contain long strings of zero bits.
1618
          In order to make writing addresses
1619
 
1620
          containing zero bits easier a special syntax is available to com-
1621
          press the zeros.  The use of ``::'' indicates multiple groups of 16
1622
          bits of zeros.  The ``::'' can only appear once in an address.  The
1623
          ``::'' can also be used to compress the leading and/or trailing
1624
          zeros in an address.
1625
 
1626
          For example the following addresses:
1627
 
1628
                1080:0:0:0:8:800:200C:417A  a unicast address
1629
                FF01:0:0:0:0:0:0:43         a multicast address
1630
                0:0:0:0:0:0:0:1             the loopback address
1631
                0:0:0:0:0:0:0:0             the unspecified addresses
1632
 
1633
          may be represented as:
1634
 
1635
                1080::8:800:200C:417A       a unicast address
1636
                FF01::43                    a multicast address
1637
                ::1                         the loopback address
1638
                ::                          the unspecified addresses
1639
 
1640
     3.   An alternative form that is sometimes more convenient when dealing
1641
          with a mixed environment of IPv4 and IPv6 nodes is
1642
          x:x:x:x:x:x:d.d.d.d, where the 'x's are the hexadecimal values of
1643
          the six high-order 16-bit pieces of the address, and the 'd's are
1644
          the decimal values of the four low-order 8-bit pieces of the address
1645
          (standard IPv4 representation).  Examples:
1646
 
1647
                0:0:0:0:0:0:13.1.68.3
1648
                0:0:0:0:0:FFFF:129.144.52.38
1649
 
1650
          or in compressed form:
1651
 
1652
                ::13.1.68.3
1653
                ::FFFF:129.144.52.38
1654
 
1655
DIAGNOSTICS
1656
     The constant INADDR_NONE is returned by inet_addr() and inet_network()
1657
     for malformed requests.
1658
 
1659
SEE ALSO
1660
     byteorder(3), gethostbyname(3), getnetent(3), inet_net(3), hosts(5),
1661
     networks(5)
1662
 
1663
STANDARDS
1664
     The inet_ntop and inet_pton functions conforms to the IETF IPv6 BSD API
1665
     and address formatting specifications.  Note that inet_pton does not
1666
     accept 1-, 2-, or 3-part dotted addresses; all four parts must be speci-
1667
     fied.  This is a narrower input set than that accepted by inet_aton.
1668
 
1669
HISTORY
1670
     The inet_addr, inet_network, inet_makeaddr, inet_lnaof and inet_netof
1671
     functions appeared in 4.2BSD.  The inet_aton and inet_ntoa functions
1672
     appeared in 4.3BSD.  The inet_pton and inet_ntop functions appeared in
1673
     BIND 4.9.4.
1674
 
1675
BUGS
1676
     The value INADDR_NONE (0xffffffff) is a valid broadcast address, but
1677
     inet_addr() cannot return that value without indicating failure.  Also,
1678
     inet_addr() should have been designed to return a struct in_addr.  The
1679
     newer inet_aton() function does not share these problems, and almost all
1680
     existing code should be modified to use inet_aton() instead.
1681
 
1682
     The problem of host byte ordering versus network byte ordering is confus-
1683
     ing.
1684
 
1685
     The string returned by inet_ntoa() resides in a static memory area.
1686
 
1687
BSD                              June 18, 1997                             BSD
1688
    
1689
  
1690
 
1691
  
1692
    inet6_option_space
1693
    
1694
INET6_OPTION_SPACE(3)   System Library Functions Manual  INET6_OPTION_SPACE(3)
1695
 
1696
NAME
1697
     inet6_option_space, inet6_option_init, inet6_option_append,
1698
     inet6_option_alloc, inet6_option_next, inet6_option_find - IPv6 Hop-by-
1699
     Hop and Destination Options manipulation
1700
 
1701
SYNOPSIS
1702
     #include <netinet/in.h>
1703
 
1704
     int
1705
     inet6_option_space(int nbytes);
1706
 
1707
     int
1708
     inet6_option_init(void *bp, struct cmsghdr **cmsgp, int type);
1709
 
1710
     int
1711
     inet6_option_append(struct cmsghdr *cmsg, const u_int8_t *typep,
1712
             int multx, int plusy);
1713
 
1714
     u_int8_t *
1715
     inet6_option_alloc(struct cmsghdr *cmsg, int datalen, int multx,
1716
             int plusy);;
1717
 
1718
     int
1719
     inet6_option_next(const struct cmsghdr *cmsg, u_int8_t **tptrp);
1720
 
1721
     int
1722
     inet6_option_find(const struct cmsghdr *cmsg, u_int8_t **tptrp,
1723
             int type);
1724
 
1725
DESCRIPTION
1726
     Building and parsing the Hop-by-Hop and Destination options is compli-
1727
     cated due to alignment constranints, padding and ancillary data manipula-
1728
     tion.  RFC2292 defines a set of functions to help the application.  The
1729
     function prototypes for these functions are all in the <netinet/in.h>
1730
     header.
1731
 
1732
   inet6_option_space
1733
     inet6_option_space() returns the number of bytes required to hold an
1734
     option when it is stored as ancillary data, including the cmsghdr struc-
1735
     ture at the beginning, and any padding at the end (to make its size a
1736
     multiple of 8 bytes).  The argument is the size of the structure defining
1737
     the option, which must include any pad bytes at the beginning (the value
1738
     y in the alignment term ``xn + y''), the type byte, the length byte, and
1739
     the option data.
1740
 
1741
     Note: If multiple options are stored in a single ancillary data object,
1742
     which is the recommended technique, this function overestimates the
1743
     amount of space required by the size of N-1 cmsghdr structures, where N
1744
     is the number of options to be stored in the object.  This is of little
1745
     consequence, since it is assumed that most Hop-by-Hop option headers and
1746
     Destination option headers carry only one option (appendix B of
1747
     [RFC-2460]).
1748
 
1749
   inet6_option_init
1750
     inet6_option_init() is called once per ancillary data object that will
1751
     contain either Hop-by-Hop or Destination options.  It returns 0 on suc-
1752
     cess or -1 on an error.
1753
 
1754
     bp is a pointer to previously allocated space that will contain the
1755
     ancillary data object.  It must be large enough to contain all the indi-
1756
     vidual options to be added by later calls to inet6_option_append() and
1757
     inet6_option_alloc().
1758
 
1759
     cmsgp is a pointer to a pointer to a cmsghdr structure.  *cmsgp is ini-
1760
     tialized by this function to point to the cmsghdr structure constructed
1761
     by this function in the buffer pointed to by bp.
1762
 
1763
     type is either IPV6_HOPOPTS or IPV6_DSTOPTS.  This type is stored in the
1764
     cmsg_type member of the cmsghdr structure pointed to by *cmsgp.
1765
 
1766
   inet6_option_append
1767
     This function appends a Hop-by-Hop option or a Destination option into an
1768
     ancillary data object that has been initialized by inet6_option_init().
1769
     This function returns 0 if it succeeds or -1 on an error.
1770
 
1771
     cmsg is a pointer to the cmsghdr structure that must have been initial-
1772
     ized by inet6_option_init().
1773
 
1774
     typep is a pointer to the 8-bit option type.  It is assumed that this
1775
     field is immediately followed by the 8-bit option data length field,
1776
     which is then followed immediately by the option data.  The caller ini-
1777
     tializes these three fields (the type-length-value, or TLV) before call-
1778
     ing this function.
1779
 
1780
     The option type must have a value from 2 to 255, inclusive.  (0 and 1 are
1781
     reserved for the Pad1 and PadN options, respectively.)
1782
 
1783
     The option data length must have a value between 0 and 255, inclusive,
1784
     and is the length of the option data that follows.
1785
 
1786
     multx is the value x in the alignment term ``xn + y''.  It must have a
1787
     value of 1, 2, 4, or 8.
1788
 
1789
     plusy is the value y in the alignment term ``xn + y''.  It must have a
1790
     value between 0 and 7, inclusive.
1791
 
1792
   inet6_option_alloc
1793
     This function appends a Hop-by-Hop option or a Destination option into an
1794
     ancillary data object that has been initialized by inet6_option_init().
1795
     This function returns a pointer to the 8-bit option type field that
1796
     starts the option on success, or NULL on an error.
1797
 
1798
     The difference between this function and inet6_option_append() is that
1799
     the latter copies the contents of a previously built option into the
1800
     ancillary data object while the current function returns a pointer to the
1801
     space in the data object where the option's TLV must then be built by the
1802
     caller.
1803
 
1804
     cmsg is a pointer to the cmsghdr structure that must have been initial-
1805
     ized by inet6_option_init().
1806
 
1807
     datalen is the value of the option data length byte for this option.
1808
     This value is required as an argument to allow the function to determine
1809
     if padding must be appended at the end of the option.  (The
1810
     inet6_option_append() function does not need a data length argument since
1811
     the option data length must already be stored by the caller.)
1812
 
1813
     multx is the value x in the alignment term ``xn + y''.  It must have a
1814
     value of 1, 2, 4, or 8.
1815
 
1816
     plusy is the value y in the alignment term ``xn + y''.  It must have a
1817
     value between 0 and 7, inclusive.
1818
 
1819
   inet6_option_next
1820
     This function processes the next Hop-by-Hop option or Destination option
1821
     in an ancillary data object.  If another option remains to be processed,
1822
     the return value of the function is 0 and *tptrp points to the 8-bit
1823
     option type field (which is followed by the 8-bit option data length,
1824
     followed by the option data).  If no more options remain to be processed,
1825
     the return value is -1 and *tptrp is NULL.  If an error occurs, the
1826
     return value is -1 and *tptrp is not NULL.
1827
 
1828
     cmsg is a pointer to cmsghdr structure of which cmsg_level equals
1829
     IPPROTO_IPV6 and cmsg_type equals either IPV6_HOPOPTS or IPV6_DSTOPTS.
1830
 
1831
     tptrp is a pointer to a pointer to an 8-bit byte and *tptrp is used by
1832
     the function to remember its place in the ancillary data object each time
1833
     the function is called.  The first time this function is called for a
1834
     given ancillary data object, *tptrp must be set to NULL.
1835
 
1836
     Each time this function returns success, *tptrp points to the 8-bit
1837
     option type field for the next option to be processed.
1838
 
1839
   inet6_option_find
1840
     This function is similar to the previously described inet6_option_next()
1841
     function, except this function lets the caller specify the option type to
1842
     be searched for, instead of always returning the next option in the
1843
     ancillary data object.  cmsg is a pointer to cmsghdr structure of which
1844
     cmsg_level equals IPPROTO_IPV6 and cmsg_type equals either IPV6_HOPOPTS
1845
     or IPV6_DSTOPTS.
1846
 
1847
     tptrp is a pointer to a pointer to an 8-bit byte and *tptrp is used by
1848
     the function to remember its place in the ancillary data object each time
1849
     the function is called.  The first time this function is called for a
1850
     given ancillary data object, *tptrp must be set to NULL.  ~ This function
1851
     starts searching for an option of the specified type beginning after the
1852
     value of *tptrp.  If an option of the specified type is located, this
1853
     function returns 0 and *tptrp points to the 8- bit option type field for
1854
     the option of the specified type.  If an option of the specified type is
1855
     not located, the return value is -1 and *tptrp is NULL.  If an error
1856
     occurs, the return value is -1 and *tptrp is not NULL.
1857
 
1858
DIAGNOSTICS
1859
     inet6_option_init() and inet6_option_append() return 0 on success or -1
1860
     on an error.
1861
 
1862
     inet6_option_alloc() returns NULL on an error.
1863
 
1864
     On errors, inet6_option_next() and inet6_option_find() return -1 setting
1865
     *tptrp to non NULL value.
1866
 
1867
EXAMPLES
1868
     RFC2292 gives comprehensive examples in chapter 6.
1869
 
1870
SEE ALSO
1871
     W. Stevens and M. Thomas, Advanced Sockets API for IPv6, RFC2292,
1872
     February 1998.
1873
 
1874
     S. Deering and R. Hinden, Internet Protocol, Version 6 (IPv6)
1875
     Specification, RFC2460, December 1998.
1876
 
1877
HISTORY
1878
     The implementation first appeared in KAME advanced networking kit.
1879
 
1880
STANDARDS
1881
     The functions are documented in ``Advanced Sockets API for IPv6''
1882
     (RFC2292).
1883
 
1884
BUGS
1885
     The text was shamelessly copied from RFC2292.
1886
 
1887
BSD                            December 10, 1999                           BSD
1888
    
1889
  
1890
 
1891
  
1892
    inet6_rthdr_space
1893
    
1894
INET6_RTHDR_SPACE(3)    System Library Functions Manual   INET6_RTHDR_SPACE(3)
1895
 
1896
NAME
1897
     inet6_rthdr_space, inet6_rthdr_init, inet6_rthdr_add,
1898
     inet6_rthdr_lasthop, inet6_rthdr_reverse, inet6_rthdr_segments,
1899
     inet6_rthdr_getaddr, inet6_rthdr_getflags - IPv6 Routing Header Options
1900
     manipulation
1901
 
1902
SYNOPSIS
1903
     #include <netinet/in.h>
1904
 
1905
     size_t
1906
     inet6_rthdr_space(int type, int segments);
1907
 
1908
     struct cmsghdr *
1909
     inet6_rthdr_init(void *bp, int type);
1910
 
1911
     int
1912
     inet6_rthdr_add(struct cmsghdr *cmsg, const struct in6_addr *addr,
1913
             unsigned int flags);
1914
 
1915
     int
1916
     inet6_rthdr_lasthop(struct cmsghdr *cmsg, unsigned int flags);
1917
 
1918
     int
1919
     inet6_rthdr_reverse(const struct cmsghdr *in, struct cmsghdr *out);
1920
 
1921
     int
1922
     inet6_rthdr_segments(const struct cmsghdr *cmsg);
1923
 
1924
     struct in6_addr *
1925
     inet6_rthdr_getaddr(struct cmsghdr *cmsg, int index);
1926
 
1927
     int
1928
     inet6_rthdr_getflags(const struct cmsghdr *cmsg, int index);
1929
 
1930
DESCRIPTION
1931
     RFC2292 IPv6 advanced API defines eight functions that the application
1932
     calls to build and examine a Routing header.  Four functions build a
1933
     Routing header:
1934
 
1935
     inet6_rthdr_space() return #bytes required for ancillary data
1936
 
1937
     inet6_rthdr_init() initialize ancillary data for Routing header
1938
 
1939
     inet6_rthdr_add() add IPv6 address & flags to Routing header
1940
 
1941
     inet6_rthdr_lasthop() specify the flags for the final hop
1942
 
1943
     Four functions deal with a returned Routing header:
1944
 
1945
     inet6_rthdr_reverse() reverse a Routing header
1946
 
1947
     inet6_rthdr_segments() return #segments in a Routing header
1948
 
1949
     inet6_rthdr_getaddr() fetch one address from a Routing header
1950
 
1951
     inet6_rthdr_getflags() fetch one flag from a Routing header
1952
 
1953
     The function prototypes for these functions are all in the <netinet/in.h>
1954
     header.
1955
 
1956
   inet6_rthdr_space
1957
     This function returns the number of bytes required to hold a Routing
1958
     header of the specified type containing the specified number of segments
1959
     (addresses).  For an IPv6 Type 0 Routing header, the number of segments
1960
     must be between 1 and 23, inclusive.  The return value includes the size
1961
     of the cmsghdr structure that precedes the Routing header, and any
1962
     required padding.
1963
 
1964
     If the return value is 0, then either the type of the Routing header is
1965
     not supported by this implementation or the number of segments is invalid
1966
     for this type of Routing header.
1967
 
1968
     Note: This function returns the size but does not allocate the space
1969
     required for the ancillary data.  This allows an application to allocate
1970
     a larger buffer, if other ancillary data objects are desired, since all
1971
     the ancillary data objects must be specified to sendmsg(2) as a single
1972
     msg_control buffer.
1973
 
1974
   inet6_rthdr_init
1975
     This function initializes the buffer pointed to by bp to contain a
1976
     cmsghdr structure followed by a Routing header of the specified type.
1977
     The cmsg_len member of the cmsghdr structure is initialized to the size
1978
     of the structure plus the amount of space required by the Routing header.
1979
     The cmsg_level and cmsg_type members are also initialized as required.
1980
 
1981
     The caller must allocate the buffer and its size can be determined by
1982
     calling inet6_rthdr_space().
1983
 
1984
     Upon success the return value is the pointer to the cmsghdr structure,
1985
     and this is then used as the first argument to the next two functions.
1986
     Upon an error the return value is NULL.
1987
 
1988
   inet6_rthdr_add
1989
     This function adds the address pointed to by addr to the end of the Rout-
1990
     ing header being constructed and sets the type of this hop to the value
1991
     of flags.  For an IPv6 Type 0 Routing header, flags must be either
1992
     IPV6_RTHDR_LOOSE or IPV6_RTHDR_STRICT.
1993
 
1994
     If successful, the cmsg_len member of the cmsghdr structure is updated to
1995
     account for the new address in the Routing header and the return value of
1996
     the function is 0.  Upon an error the return value of the function is -1.
1997
 
1998
   inet6_rthdr_lasthop
1999
     This function specifies the Strict/Loose flag for the final hop of a
2000
     Routing header.  For an IPv6 Type 0 Routing header, flags must be either
2001
     IPV6_RTHDR_LOOSE or IPV6_RTHDR_STRICT.
2002
 
2003
     The return value of the function is 0 upon success, or -1 upon an error.
2004
 
2005
     Notice that a Routing header specifying N intermediate nodes requires N+1
2006
     Strict/Loose flags.  This requires N calls to inet6_rthdr_add() followed
2007
     by one call to inet6_rthdr_lasthop().
2008
 
2009
   inet6_rthdr_reverse
2010
     This function takes a Routing header that was received as ancillary data
2011
     (pointed to by the first argument, in) and writes a new Routing header
2012
     that sends datagrams along the reverse of that route.  Both arguments are
2013
     allowed to point to the same buffer (that is, the reversal can occur in
2014
     place).
2015
 
2016
     The return value of the function is 0 on success, or -1 upon an error.
2017
 
2018
   inet6_rthdr_segments
2019
     This function returns the number of segments (addresses) contained in the
2020
     Routing header described by cmsg.  On success the return value is between
2021
     1 and 23, inclusive.  The return value of the function is -1 upon an
2022
     error.
2023
 
2024
   inet6_rthdr_getaddr
2025
     This function returns a pointer to the IPv6 address specified by index
2026
     (which must have a value between 1 and the value returned by
2027
     inet6_rthdr_segments()) in the Routing header described by cmsg.  An
2028
     application should first call inet6_rthdr_segments() to obtain the number
2029
     of segments in the Routing header.
2030
 
2031
     Upon an error the return value of the function is NULL.
2032
 
2033
   inet6_rthdr_getflags
2034
     This function returns the flags value specified by index (which must have
2035
     a value between 0 and the value returned by inet6_rthdr_segments()) in
2036
     the Routing header described by cmsg.  For an IPv6 Type 0 Routing header
2037
     the return value will be either IPV6_RTHDR_LOOSE or IPV6_RTHDR_STRICT.
2038
 
2039
     Upon an error the return value of the function is -1.
2040
 
2041
     Note: Addresses are indexed starting at 1, and flags starting at 0, to
2042
     maintain consistency with the terminology and figures in RFC2460.
2043
 
2044
DIAGNOSTICS
2045
     inet6_rthdr_space() returns 0 on errors.
2046
 
2047
     inet6_rthdr_add(), inet6_rthdr_lasthop() and inet6_rthdr_reverse() return
2048
 
2049
 
2050
     inet6_rthdr_init() and inet6_rthdr_getaddr() return NULL on error.
2051
 
2052
     inet6_rthdr_segments() and inet6_rthdr_getflags() return -1 on error.
2053
 
2054
EXAMPLES
2055
     RFC2292 gives comprehensive examples in chapter 8.
2056
 
2057
SEE ALSO
2058
     W. Stevens and M. Thomas, Advanced Sockets API for IPv6, RFC2292,
2059
     February 1998.
2060
 
2061
     S. Deering and R. Hinden, Internet Protocol, Version 6 (IPv6)
2062
     Specification, RFC2460, December 1998.
2063
 
2064
HISTORY
2065
     The implementation first appeared in KAME advanced networking kit.
2066
 
2067
STANDARDS
2068
     The functions are documented in ``Advanced Sockets API for IPv6''
2069
     (RFC2292).
2070
 
2071
BUGS
2072
     The text was shamelessly copied from RFC2292.
2073
 
2074
     inet6_rthdr_reverse() is not implemented yet.
2075
 
2076
BSD                            December 10, 1999                           BSD
2077
    
2078
  
2079
 
2080
  
2081
    inet_net
2082
    
2083
INET_NET(3)             System Library Functions Manual            INET_NET(3)
2084
 
2085
NAME
2086
     inet_net_ntop, inet_net_pton - Internet network number manipulation rou-
2087
     tines
2088
 
2089
SYNOPSIS
2090
     #include <sys/socket.h>
2091
     #include <netinet/in.h>
2092
     #include <arpa/inet.h>
2093
 
2094
     char *
2095
     inet_net_ntop(int af, const void *src, int bits, char *dst, size_t size);
2096
 
2097
     int
2098
     inet_net_pton(int af, const char *src, void *dst, size_t size);
2099
 
2100
DESCRIPTION
2101
     The inet_net_ntop() function converts an Internet network number from
2102
     network format (usually a struct in_addr or some other binary form, in
2103
     network byte order) to CIDR presentation format (suitable for external
2104
     display purposes).  bits is the number of bits in src that are the net-
2105
     work number.  It returns NULL if a system error occurs (in which case,
2106
     errno will have been set), or it returns a pointer to the destination
2107
     string.
2108
 
2109
     The inet_net_pton() function converts a presentation format Internet net-
2110
     work number (that is, printable form as held in a character string) to
2111
     network format (usually a struct in_addr or some other internal binary
2112
     representation, in network byte order).  It returns the number of bits
2113
     (either computed based on the class, or specified with /CIDR), or -1 if a
2114
     failure occurred (in which case errno will have been set.  It will be set
2115
     to ENOENT if the Internet network number was not valid).
2116
 
2117
     The only value for af currently supported is AF_INET.  size is the size
2118
     of the result buffer dst.
2119
 
2120
NETWORK NUMBERS (IP VERSION 4)
2121
     Internet network numbers may be specified in one of the following forms:
2122
 
2123
           a.b.c.d/bits
2124
           a.b.c.d
2125
           a.b.c
2126
           a.b
2127
           a
2128
 
2129
     When four parts are specified, each is interpreted as a byte of data and
2130
     assigned, from left to right, to the four bytes of an Internet network
2131
     number.  Note that when an Internet network number is viewed as a 32-bit
2132
     integer quantity on a system that uses little-endian byte order (such as
2133
     the Intel 386, 486, and Pentium processors) the bytes referred to above
2134
     appear as ``d.c.b.a''.  That is, little-endian bytes are ordered from
2135
     right to left.
2136
 
2137
     When a three part number is specified, the last part is interpreted as a
2138
     16-bit quantity and placed in the rightmost two bytes of the Internet
2139
     network number.  This makes the three part number format convenient for
2140
     specifying Class B network numbers as ``128.net.host''.
2141
 
2142
     When a two part number is supplied, the last part is interpreted as a
2143
     24-bit quantity and placed in the rightmost three bytes of the Internet
2144
     network number.  This makes the two part number format convenient for
2145
     specifying Class A network numbers as ``net.host''.
2146
 
2147
     When only one part is given, the value is stored directly in the Internet
2148
     network number without any byte rearrangement.
2149
 
2150
     All numbers supplied as ``parts'' in a `.' notation may be decimal,
2151
     octal, or hexadecimal, as specified in the C language (i.e., a leading 0x
2152
     or 0X implies hexadecimal; otherwise, a leading 0 implies octal; other-
2153
     wise, the number is interpreted as decimal).
2154
 
2155
SEE ALSO
2156
     byteorder(3), inet(3), networks(5)
2157
 
2158
HISTORY
2159
     The inet_net_ntop and inet_net_pton functions first appeared in BIND
2160
     4.9.4.
2161
 
2162
BSD                              June 18, 1997                             BSD
2163
    
2164
  
2165
 
2166
  
2167
    ipx
2168
    
2169
IPX(3)                  System Library Functions Manual                 IPX(3)
2170
 
2171
NAME
2172
     ipx_addr, ipx_ntoa - IPX address conversion routines
2173
 
2174
SYNOPSIS
2175
     #include <sys/types.h>
2176
     #include <netipx/ipx.h>
2177
 
2178
     struct ipx_addr
2179
     ipx_addr(const char *cp);
2180
 
2181
     char *
2182
     ipx_ntoa(struct ipx_addr ipx);
2183
 
2184
DESCRIPTION
2185
     The routine ipx_addr() interprets character strings representing IPX
2186
     addresses, returning binary information suitable for use in system calls.
2187
     The routine ipx_ntoa() takes IPX addresses and returns ASCII strings rep-
2188
     resenting the address in a notation in common use:
2189
 
2190
           <network number>.<host number>.<port number>
2191
 
2192
     Trailing zero fields are suppressed, and each number is printed in hex-
2193
     adecimal, in a format suitable for input to ipx_addr().  Any fields lack-
2194
     ing super-decimal digits will have a trailing `H' appended.
2195
 
2196
     An effort has been made to ensure that ipx_addr() be compatible with most
2197
     formats in common use.  It will first separate an address into 1 to 3
2198
     fields using a single delimiter chosen from period (`.'), colon (`:'), or
2199
     pound-sign (`#').  Each field is then examined for byte separators (colon
2200
     or period).  If there are byte separators, each subfield separated is
2201
     taken to be a small hexadecimal number, and the entirety is taken as a
2202
     network-byte-ordered quantity to be zero extended in the high-network-
2203
     order bytes.  Next, the field is inspected for hyphens, in which case the
2204
     field is assumed to be a number in decimal notation with hyphens separat-
2205
     ing the millenia.  Next, the field is assumed to be a number: It is
2206
     interpreted as hexadecimal if there is a leading `0x' (as in C), a trail-
2207
     ing `H' (as in Mesa), or there are any super-decimal digits present.  It
2208
     is interpreted as octal is there is a leading `0' and there are no super-
2209
     octal digits.  Otherwise, it is converted as a decimal number.
2210
 
2211
RETURN VALUES
2212
     None.  (See BUGS.)
2213
 
2214
SEE ALSO
2215
     ns(4), hosts(5), networks(5)
2216
 
2217
HISTORY
2218
     The precursor ns_addr() and ns_ntoa() functions appeared in 4.3BSD.
2219
 
2220
BUGS
2221
     The string returned by ipx_ntoa() resides in a static memory area.  The
2222
     function ipx_addr() should diagnose improperly formed input, and there
2223
     should be an unambiguous way to recognize this.
2224
 
2225
BSD                              June 4, 1993                              BSD
2226
    
2227
  
2228
 
2229
  
2230
    iso_addr
2231
    
2232
ISO_ADDR(3)             System Library Functions Manual            ISO_ADDR(3)
2233
 
2234
NAME
2235
     iso_addr, iso_ntoa - network address conversion routines for Open System
2236
     Interconnection
2237
 
2238
SYNOPSIS
2239
     #include <sys/types.h>
2240
     #include <netiso/iso.h>
2241
 
2242
     struct iso_addr *
2243
     iso_addr(char *cp);
2244
 
2245
     char *
2246
     iso_ntoa(struct iso_addr *isoa);
2247
 
2248
DESCRIPTION
2249
     The routine iso_addr() interprets character strings representing OSI
2250
     addresses, returning binary information suitable for use in system calls.
2251
     The routine iso_ntoa() takes OSI addresses and returns ASCII strings rep-
2252
     resenting NSAPs (network service access points) in a notation inverse to
2253
     that accepted by iso_addr().
2254
 
2255
     Unfortunately, no universal standard exists for representing OSI network
2256
     addresses.
2257
 
2258
     The format employed by iso_addr() is a sequence of hexadecimal ``digits''
2259
     (optionally separated by periods), of the form:
2260
 
2261
           <hex digits>.<hex digits>.<hex digits>
2262
 
2263
     Each pair of hexadecimal digits represents a byte with the leading digit
2264
     indicating the higher-ordered bits.  A period following an even number of
2265
     bytes has no effect (but may be used to increase legibility).  A period
2266
     following an odd number of bytes has the effect of causing the byte of
2267
     address being translated to have its higher order bits filled with zeros.
2268
 
2269
RETURN VALUES
2270
     iso_ntoa() always returns a null terminated string.  iso_addr() always
2271
     returns a pointer to a struct iso_addr.  (See BUGS.)
2272
 
2273
SEE ALSO
2274
     iso(4)
2275
 
2276
HISTORY
2277
     The iso_addr() and iso_ntoa() functions appeared in 4.3BSD-Reno.
2278
 
2279
BUGS
2280
     The returned values reside in a static memory area.
2281
 
2282
     The function iso_addr() should diagnose improperly formed input, and
2283
     there should be an unambiguous way to recognize this.
2284
 
2285
BSD                              June 4, 1993                              BSD
2286
    
2287
  
2288
 
2289
  
2290
    link_addr
2291
    
2292
LINK_ADDR(3)            System Library Functions Manual           LINK_ADDR(3)
2293
 
2294
NAME
2295
     link_addr, link_ntoa - elementary address specification routines for link
2296
     level access
2297
 
2298
SYNOPSIS
2299
     #include <sys/types.h>
2300
     #include <sys/socket.h>
2301
     #include <net/if_dl.h>
2302
 
2303
     void
2304
     link_addr(const char *addr, struct sockaddr_dl *sdl);
2305
 
2306
     char *
2307
     link_ntoa(const struct sockaddr_dl *sdl);
2308
 
2309
DESCRIPTION
2310
     The link_addr() function interprets character strings representing link-
2311
     level addresses, returning binary information suitable for use in system
2312
     calls.  link_ntoa() takes a link-level address and returns an ASCII
2313
     string representing some of the information present, including the link
2314
     level address itself, and the interface name or number, if present.  This
2315
     facility is experimental and is still subject to change.
2316
 
2317
     For link_addr(), the string addr may contain an optional network inter-
2318
     face identifier of the form ``name unit-number'', suitable for the first
2319
     argument to ifconfig(8), followed in all cases by a colon and an inter-
2320
     face address in the form of groups of hexadecimal digits separated by
2321
     periods.  Each group represents a byte of address; address bytes are
2322
     filled left to right from low order bytes through high order bytes.
2323
 
2324
     Thus le0:8.0.9.13.d.30 represents an Ethernet address to be transmitted
2325
     on the first Lance Ethernet interface.
2326
 
2327
RETURN VALUES
2328
     link_ntoa() always returns a null-terminated string.  link_addr() has no
2329
     return value.  (See BUGS.)
2330
 
2331
SEE ALSO
2332
     iso(4), ifconfig(8)
2333
 
2334
HISTORY
2335
     The link_addr() and link_ntoa() functions appeared in 4.3BSD-Reno.
2336
 
2337
BUGS
2338
     The returned values for link_ntoa reside in a static memory area.
2339
 
2340
     The function link_addr() should diagnose improperly formed input, and
2341
     there should be an unambiguous way to recognize this.
2342
 
2343
     If the sdl_len field of the link socket address sdl is 0, link_ntoa()
2344
     will not insert a colon before the interface address bytes.  If this
2345
     translated address is given to link_addr() without inserting an initial
2346
     colon, the latter will not interpret it correctly.
2347
 
2348
BSD                              July 28, 1993                             BSD
2349
    
2350
  
2351
 
2352
  
2353
    net_addrcmp
2354
    
2355
NET_ADDRCMP(3)          System Library Functions Manual         NET_ADDRCMP(3)
2356
 
2357
NAME
2358
     net_addrcmp - compare socket address structures
2359
 
2360
SYNOPSIS
2361
     #include <netdb.h>
2362
 
2363
     int
2364
     net_addrcmp(struct sockaddr *sa1, struct sockaddr *sa2);
2365
 
2366
DESCRIPTION
2367
     The net_addrcmp() function compares two socket address structures, sa1
2368
     and sa2.
2369
 
2370
RETURN VALUES
2371
     If sa1 and sa2 are for the same address, net_addrcmp() returns 0.
2372
 
2373
     The sa_len fields are compared first.  If they do not match,
2374
     net_addrcmp() returns -1 or 1 if sa1->sa_len is less than or greater than
2375
     sa2->sa_len, respectively.
2376
 
2377
     Next, the sa_family members are compared.  If they do not match,
2378
     net_addrcmp() returns -1 or 1 if sa1->sa_family is less than or greater
2379
     than sa2->sa_family, respectively.
2380
 
2381
     Lastly, if each socket address structure's sa_len and sa_family fields
2382
     match, the protocol-specific data (the sa_data field) is compared.  If
2383
     there's a match, both sa1 and sa2 must refer to the same address, and 0
2384
     is returned; otherwise, a value >0 or <0 is returned.
2385
 
2386
HISTORY
2387
     A net_addrcmp() function was added in OpenBSD 2.5.
2388
 
2389
BSD                              July 3, 1999                              BSD
2390
    
2391
  
2392
 
2393
  
2394
    ns
2395
    
2396
NS(3)                   System Library Functions Manual                  NS(3)
2397
 
2398
NAME
2399
     ns_addr, ns_ntoa - Xerox NS(tm) address conversion routines
2400
 
2401
SYNOPSIS
2402
     #include <sys/types.h>
2403
     #include <netns/ns.h>
2404
 
2405
     struct ns_addr
2406
     ns_addr(char *cp);
2407
 
2408
     char *
2409
     ns_ntoa(struct ns_addr ns);
2410
 
2411
DESCRIPTION
2412
     The routine ns_addr() interprets character strings representing XNS
2413
     addresses, returning binary information suitable for use in system calls.
2414
     The routine ns_ntoa() takes XNS addresses and returns ASCII strings rep-
2415
     resenting the address in a notation in common use in the Xerox Develop-
2416
     ment Environment:
2417
 
2418
           <network number>.<host number>.<port number>
2419
 
2420
     Trailing zero fields are suppressed, and each number is printed in hex-
2421
     adecimal, in a format suitable for input to ns_addr().  Any fields lack-
2422
     ing super-decimal digits will have a trailing `H' appended.
2423
 
2424
     Unfortunately, no universal standard exists for representing XNS
2425
     addresses.  An effort has been made to ensure that ns_addr() be compati-
2426
     ble with most formats in common use.  It will first separate an address
2427
     into 1 to 3 fields using a single delimiter chosen from period (`.'),
2428
     colon (`:'), or pound-sign `#'.  Each field is then examined for byte
2429
     separators (colon or period).  If there are byte separators, each sub-
2430
     field separated is taken to be a small hexadecimal number, and the
2431
     entirety is taken as a network-byte-ordered quantity to be zero extended
2432
     in the high-network-order bytes.  Next, the field is inspected for
2433
     hyphens, in which case the field is assumed to be a number in decimal
2434
     notation with hyphens separating the millenia.  Next, the field is
2435
     assumed to be a number: It is interpreted as hexadecimal if there is a
2436
     leading `0x' (as in C), a trailing `H' (as in Mesa), or there are any
2437
     super-decimal digits present.  It is interpreted as octal is there is a
2438
     leading `0' and there are no super-octal digits.  Otherwise, it is con-
2439
     verted as a decimal number.
2440
 
2441
RETURN VALUES
2442
     None.  (See BUGS.)
2443
 
2444
SEE ALSO
2445
     hosts(5), networks(5)
2446
 
2447
HISTORY
2448
     The ns_addr() and ns_toa() functions appeared in 4.3BSD.
2449
 
2450
BUGS
2451
     The string returned by ns_ntoa() resides in a static memory area.  The
2452
     function ns_addr() should diagnose improperly formed input, and there
2453
     should be an unambiguous way to recognize this.
2454
 
2455
BSD                              June 4, 1993                              BSD
2456
    
2457
  
2458
 
2459
  
2460
    resolver
2461
    
2462
RESOLVER(3)             System Library Functions Manual            RESOLVER(3)
2463
 
2464
NAME
2465
     res_query, res_search, res_mkquery, res_send, res_init, dn_comp,
2466
     dn_expand - resolver routines
2467
 
2468
SYNOPSIS
2469
     #include <sys/types.h>
2470
     #include <netinet/in.h>
2471
     #include <arpa/nameser.h>
2472
     #include <resolv.h>
2473
 
2474
     int
2475
     res_query(char *dname, int class, int type, u_char *answer, int anslen);
2476
 
2477
     int
2478
     res_search(char *dname, int class, int type, u_char *answer, int anslen);
2479
 
2480
     int
2481
     res_mkquery(int op, char *dname, int class, int type, char *data,
2482
             int datalen, struct rrec *newrr, char *buf, int buflen);
2483
 
2484
     int
2485
     res_send(char *msg, int msglen, char *answer, int anslen);
2486
 
2487
     int
2488
     res_init(void);
2489
 
2490
     int
2491
     dn_comp(char *exp_dn, char *comp_dn, int length, char **dnptrs,
2492
             char **lastdnptr);
2493
 
2494
     int
2495
     dn_expand(u_char *msg, u_char *eomorig, u_char *comp_dn, u_char *exp_dn,
2496
             int length);
2497
 
2498
DESCRIPTION
2499
     These routines are used for making, sending, and interpreting query and
2500
     reply messages with Internet domain name servers.
2501
 
2502
     Global configuration and state information that is used by the resolver
2503
     routines is kept in the structure _res.  Most of the values have reason-
2504
     able defaults and can be ignored.  Options stored in _res.options are
2505
     defined in <resolv.h> and are as follows.  Options are stored as a simple
2506
     bit mask containing the bitwise OR of the options enabled.
2507
 
2508
     RES_INIT       True if the initial name server address and default domain
2509
                    name are initialized (i.e., res_init() has been called).
2510
 
2511
     RES_DEBUG      Print debugging messages.
2512
 
2513
     RES_AAONLY     Accept authoritative answers only.  With this option,
2514
                    res_send() should continue until it finds an authoritative
2515
                    answer or finds an error.  Currently this is not imple-
2516
                    mented.
2517
 
2518
     RES_USEVC      Use TCP connections for queries instead of UDP datagrams.
2519
 
2520
     RES_STAYOPEN   Used with RES_USEVC to keep the TCP connection open
2521
                    between queries.  This is useful only in programs that
2522
                    regularly do many queries.  UDP should be the normal mode
2523
                    used.
2524
 
2525
     RES_IGNTC      Unused currently (ignore truncation errors, i.e., don't
2526
                    retry with TCP).
2527
 
2528
     RES_RECURSE    Set the recursion-desired bit in queries.  This is the
2529
                    default.  (res_send() does not do iterative queries and
2530
                    expects the name server to handle recursion.)
2531
 
2532
     RES_DEFNAMES   If set, res_search() will append the default domain name
2533
                    to single-component names (those that do not contain a
2534
                    dot).  This option is enabled by default.
2535
 
2536
     RES_DNSRCH     If this option is set, res_search() will search for host
2537
                    names in the current domain and in parent domains; see
2538
                    hostname(7).  This is used by the standard host lookup
2539
                    routine gethostbyname(3).  This option is enabled by
2540
                    default.
2541
 
2542
     RES_USE_INET6  Enables support for IPv6-only applications.  This causes
2543
                    IPv4 addresses to be returned as an IPv4 mapped address.
2544
                    For example, 10.1.1.1 will be returned as ::ffff:10.1.1.1.
2545
                    The option is not meaningful on OpenBSD.
2546
 
2547
     The res_init() routine reads the configuration file (if any; see
2548
     resolv.conf(5)) to get the default domain name, search list, and the
2549
     Internet address of the local name server(s).  If no server is config-
2550
     ured, the host running the resolver is tried.  The current domain name is
2551
     defined by the hostname if not specified in the configuration file; it
2552
     can be overridden by the environment variable LOCALDOMAIN.  This environ-
2553
     ment variable may contain several blank-separated tokens if you wish to
2554
     override the search list on a per-process basis.  This is similar to the
2555
     search command in the configuration file.  Another environment variable
2556
     RES_OPTIONS can be set to override certain internal resolver options
2557
     which are otherwise set by changing fields in the _res structure or are
2558
     inherited from the configuration file's options command.  The syntax of
2559
     the RES_OPTIONS environment variable is explained in resolv.conf(5).
2560
     Initialization normally occurs on the first call to one of the following
2561
     routines.
2562
 
2563
     The res_query() function provides an interface to the server query mecha-
2564
     nism.  It constructs a query, sends it to the local server, awaits a
2565
     response, and makes preliminary checks on the reply.  The query requests
2566
     information of the specified type and class for the specified fully qual-
2567
     ified domain name dname.  The reply message is left in the answer buffer
2568
     with length anslen supplied by the caller.
2569
 
2570
     The res_search() routine makes a query and awaits a response like
2571
     res_query(), but in addition, it implements the default and search rules
2572
     controlled by the RES_DEFNAMES and RES_DNSRCH options.  It returns the
2573
     first successful reply.
2574
 
2575
     The remaining routines are lower-level routines used by res_query().  The
2576
     res_mkquery() function constructs a standard query message and places it
2577
     in buf.  It returns the size of the query, or -1 if the query is larger
2578
     than buflen.  The query type op is usually QUERY, but can be any of the
2579
     query types defined in <arpa/nameser.h>.  The domain name for the query
2580
     is given by dname.  newrr is currently unused but is intended for making
2581
     update messages.
2582
 
2583
     The res_send() routine sends a pre-formatted query and returns an answer.
2584
     It will call res_init() if RES_INIT is not set, send the query to the
2585
     local name server, and handle timeouts and retries.  The length of the
2586
     reply message is returned, or -1 if there were errors.
2587
 
2588
     The dn_comp() function compresses the domain name exp_dn and stores it in
2589
     comp_dn.  The size of the compressed name is returned or -1 if there were
2590
     errors.  The size of the array pointed to by comp_dn is given by length.
2591
     The compression uses an array of pointers dnptrs to previously compressed
2592
     names in the current message.  The first pointer points to the beginning
2593
     of the message and the list ends with NULL.  The limit to the array is
2594
     specified by lastdnptr.  A side effect of dn_comp() is to update the list
2595
     of pointers for labels inserted into the message as the name is com-
2596
     pressed.  If dnptr is NULL, names are not compressed.  If lastdnptr is
2597
     NULL, the list of labels is not updated.
2598
 
2599
     The dn_expand() entry expands the compressed domain name comp_dn to a
2600
     full domain name The compressed name is contained in a query or reply
2601
     message; msg is a pointer to the beginning of the message.  The uncom-
2602
     pressed name is placed in the buffer indicated by exp_dn which is of size
2603
     length.  The size of compressed name is returned or -1 if there was an
2604
     error.
2605
 
2606
FILES
2607
     /etc/resolv.conf configuration file see resolv.conf(5).
2608
 
2609
SEE ALSO
2610
     gethostbyname(3), resolv.conf(5), hostname(7), named(8)
2611
 
2612
     RFC1032, RFC1033, RFC1034, RFC1035, RFC1535, RFC974
2613
 
2614
     Name Server Operations Guide for BIND.
2615
 
2616
HISTORY
2617
     The res_query function appeared in 4.3BSD.
2618
 
2619
BSD                              June 4, 1993                              BSD
2620
    
2621
  
2622
 
2623
  
2624
    accept
2625
    
2626
ACCEPT(2)                     System Calls Manual                    ACCEPT(2)
2627
 
2628
NAME
2629
     accept - accept a connection on a socket
2630
 
2631
SYNOPSIS
2632
     #include <sys/types.h>
2633
     #include <sys/socket.h>
2634
 
2635
     int
2636
     accept(int s, struct sockaddr *addr, socklen_t *addrlen);
2637
 
2638
DESCRIPTION
2639
     The argument s is a socket that has been created with socket(2), bound to
2640
     an address with bind(2), and is listening for connections after a
2641
     listen(2).  The accept() argument extracts the first connection request
2642
     on the queue of pending connections, creates a new socket with the same
2643
     properties of s, and allocates a new file descriptor for the socket.  If
2644
     no pending connections are present on the queue, and the socket is not
2645
     marked as non-blocking, accept() blocks the caller until a connection is
2646
     present.  If the socket is marked non-blocking and no pending connections
2647
     are present on the queue, accept() returns an error as described below.
2648
     The accepted socket may not be used to accept more connections.  The
2649
     original socket s remains open.
2650
 
2651
     The argument addr is a result parameter that is filled in with the
2652
     address of the connecting entity as known to the communications layer.
2653
     The exact format of the addr parameter is determined by the domain in
2654
     which the communication is occurring.  The addrlen is a value-result
2655
     parameter; it should initially contain the amount of space pointed to by
2656
     addr; on return it will contain the actual length (in bytes) of the
2657
     address returned.  This call is used with connection-based socket types,
2658
     currently with SOCK_STREAM.
2659
 
2660
     It is possible to select(2) or poll(2) a socket for the purposes of doing
2661
     an accept() by selecting it for read.
2662
 
2663
     For certain protocols which require an explicit confirmation, such as ISO
2664
     or DATAKIT, accept() can be thought of as merely dequeuing the next con-
2665
     nection request and not implying confirmation.  Confirmation can be
2666
     implied by a normal read or write on the new file descriptor, and rejec-
2667
     tion can be implied by closing the new socket.
2668
 
2669
     One can obtain user connection request data without confirming the con-
2670
     nection by issuing a recvmsg(2) call with an msg_iovlen of 0 and a non-
2671
     zero msg_controllen, or by issuing a getsockopt(2) request.  Similarly,
2672
     one can provide user connection rejection information by issuing a
2673
     sendmsg(2) call with providing only the control information, or by call-
2674
     ing setsockopt(2).
2675
 
2676
RETURN VALUES
2677
     The call returns -1 on error.  If it succeeds, it returns a non-negative
2678
     integer that is a descriptor for the accepted socket.
2679
 
2680
ERRORS
2681
     The accept() will fail if:
2682
 
2683
     [EBADF]            The descriptor is invalid.
2684
 
2685
     [ENOTSOCK]         The descriptor references a file, not a socket.
2686
 
2687
     [EOPNOTSUPP]       The referenced socket is not of type SOCK_STREAM.
2688
 
2689
     [EINVAL]           The referenced socket is not listening for connections
2690
                        (that is, listen(2) has not yet been called).
2691
 
2692
     [EFAULT]           The addr parameter is not in a writable part of the
2693
                        user address space.
2694
 
2695
     [EWOULDBLOCK]      The socket is marked non-blocking and no connections
2696
                        are present to be accepted.
2697
 
2698
     [EMFILE]           The per-process descriptor table is full.
2699
 
2700
     [ENFILE]           The system file table is full.
2701
 
2702
     [ECONNABORTED]     A connection has been aborted.
2703
 
2704
SEE ALSO
2705
     bind(2), connect(2), listen(2), poll(2), select(2), poll(2), socket(2)
2706
 
2707
HISTORY
2708
     The accept() function appeared in 4.2BSD.
2709
 
2710
BSD                            February 15, 1999                           BSD
2711
    
2712
  
2713
 
2714
  
2715
    bind
2716
    
2717
BIND(2)                       System Calls Manual                      BIND(2)
2718
 
2719
NAME
2720
     bind - bind a name to a socket
2721
 
2722
SYNOPSIS
2723
     #include <sys/types.h>
2724
     #include <sys/socket.h>
2725
 
2726
     int
2727
     bind(int s, const struct sockaddr *name, socklen_t namelen);
2728
 
2729
DESCRIPTION
2730
     bind() assigns a name to an unnamed socket.  When a socket is created
2731
     with socket(2) it exists in a name space (address family) but has no name
2732
     assigned.  bind() requests that name be assigned to the socket.
2733
 
2734
NOTES
2735
     Binding a name in the UNIX domain creates a socket in the file system
2736
     that must be deleted by the caller when it is no longer needed (using
2737
     unlink(2)).
2738
 
2739
     The rules used in name binding vary between communication domains.  Con-
2740
     sult the manual entries in section 4 for detailed information.
2741
 
2742
RETURN VALUES
2743
     If the bind is successful, a 0 value is returned.  A return value of -1
2744
     indicates an error, which is further specified in the global errno.
2745
 
2746
ERRORS
2747
     The bind() call will fail if:
2748
 
2749
     [EBADF]            S is not a valid descriptor.
2750
 
2751
     [ENOTSOCK]         S is not a socket.
2752
 
2753
     [EADDRNOTAVAIL]    The specified address is not available from the local
2754
                        machine.
2755
 
2756
     [EADDRINUSE]       The specified address is already in use.
2757
 
2758
     [EINVAL]           The socket is already bound to an address.
2759
 
2760
     [EINVAL]           The family of the socket and that requested in
2761
                        name->sa_family are not equivalent.
2762
 
2763
     [EACCES]           The requested address is protected, and the current
2764
                        user has inadequate permission to access it.
2765
 
2766
     [EFAULT]           The name parameter is not in a valid part of the user
2767
                        address space.
2768
 
2769
     The following errors are specific to binding names in the UNIX domain.
2770
 
2771
     [ENOTDIR]          A component of the path prefix is not a directory.
2772
 
2773
     [ENAMETOOLONG]     A component of a pathname exceeded {NAME_MAX} charac-
2774
                        ters, or an entire path name exceeded {PATH_MAX} char-
2775
                        acters.
2776
 
2777
     [ENOENT]           A prefix component of the path name does not exist.
2778
 
2779
     [ELOOP]            Too many symbolic links were encountered in translat-
2780
                        ing the pathname.
2781
 
2782
     [EIO]              An I/O error occurred while making the directory entry
2783
                        or allocating the inode.
2784
 
2785
     [EROFS]            The name would reside on a read-only file system.
2786
 
2787
     [EISDIR]           An empty pathname was specified.
2788
 
2789
SEE ALSO
2790
     connect(2), getsockname(2), listen(2), socket(2)
2791
 
2792
HISTORY
2793
     The bind() function call appeared in 4.2BSD.
2794
 
2795
BSD                            February 15, 1999                           BSD
2796
    
2797
  
2798
 
2799
  
2800
    connect
2801
    
2802
CONNECT(2)                    System Calls Manual                   CONNECT(2)
2803
 
2804
NAME
2805
     connect - initiate a connection on a socket
2806
 
2807
SYNOPSIS
2808
     #include <sys/types.h>
2809
     #include <sys/socket.h>
2810
 
2811
     int
2812
     connect(int s, const struct sockaddr *name, socklen_t namelen);
2813
 
2814
DESCRIPTION
2815
     The parameter s is a socket.  If it is of type SOCK_DGRAM, this call
2816
     specifies the peer with which the socket is to be associated; this
2817
     address is that to which datagrams are to be sent, and the only address
2818
     from which datagrams are to be received.  If the socket is of type
2819
     SOCK_STREAM, this call attempts to make a connection to another socket.
2820
     The other socket is specified by name, which is an address in the commu-
2821
     nications space of the socket.  Each communications space interprets the
2822
     name parameter in its own way.  Generally, stream sockets may success-
2823
     fully connect() only once; datagram sockets may use connect() multiple
2824
     times to change their association.  Datagram sockets may dissolve the
2825
     association by connecting to an invalid address, such as a null address.
2826
 
2827
RETURN VALUES
2828
     If the connection or binding succeeds, 0 is returned.  Otherwise a -1 is
2829
     returned, and a more specific error code is stored in errno.
2830
 
2831
ERRORS
2832
     The connect() call fails if:
2833
 
2834
     [EBADF]            S is not a valid descriptor.
2835
 
2836
     [ENOTSOCK]         S is a descriptor for a file, not a socket.
2837
 
2838
     [EADDRNOTAVAIL]    The specified address is not available on this
2839
                        machine.
2840
 
2841
     [EAFNOSUPPORT]     Addresses in the specified address family cannot be
2842
                        used with this socket.
2843
 
2844
     [EISCONN]          The socket is already connected.
2845
 
2846
     [ETIMEDOUT]        Connection establishment timed out without establish-
2847
                        ing a connection.
2848
 
2849
     [EINVAL]           A TCP connection with a local broadcast, the all-ones
2850
                        or a multicast address as the peer was attempted.
2851
 
2852
     [ECONNREFUSED]     The attempt to connect was forcefully rejected.
2853
 
2854
     [EINTR]            A connect was interrupted before it succeeded by the
2855
                        delivery of a signal.
2856
 
2857
     [ENETUNREACH]      The network isn't reachable from this host.
2858
 
2859
     [EADDRINUSE]       The address is already in use.
2860
 
2861
     [EFAULT]           The name parameter specifies an area outside the pro-
2862
                        cess address space.
2863
 
2864
     [EINPROGRESS]      The socket is non-blocking and the connection cannot
2865
                        be completed immediately.  It is possible to select(2)
2866
                        or poll(2) for completion by selecting the socket for
2867
                        writing, and also use getsockopt(2) with SO_ERROR to
2868
                        check for error conditions.
2869
 
2870
     [EALREADY]         The socket is non-blocking and a previous connection
2871
                        attempt has not yet been completed.
2872
 
2873
     The following errors are specific to connecting names in the UNIX domain.
2874
     These errors may not apply in future versions of the UNIX IPC domain.
2875
 
2876
     [ENOTDIR]          A component of the path prefix is not a directory.
2877
 
2878
     [ENAMETOOLONG]     A component of a pathname exceeded {NAME_MAX} charac-
2879
                        ters, or an entire path name exceeded {PATH_MAX} char-
2880
                        acters.
2881
 
2882
     [ENOENT]           The named socket does not exist.
2883
 
2884
     [EACCES]           Search permission is denied for a component of the
2885
                        path prefix.
2886
 
2887
     [EACCES]           Write access to the named socket is denied.
2888
 
2889
     [ELOOP]            Too many symbolic links were encountered in translat-
2890
                        ing the pathname.
2891
 
2892
SEE ALSO
2893
     accept(2), getsockname(2), getsockopt(2), poll(2), select(2), socket(2)
2894
 
2895
HISTORY
2896
     The connect() function call appeared in 4.2BSD.
2897
 
2898
BSD                            February 15, 1999                           BSD
2899
    
2900
  
2901
 
2902
  
2903
    getpeername
2904
    
2905
GETPEERNAME(2)                System Calls Manual               GETPEERNAME(2)
2906
 
2907
NAME
2908
     getpeername - get name of connected peer
2909
 
2910
SYNOPSIS
2911
     #include <sys/types.h>
2912
     #include <sys/socket.h>
2913
 
2914
     int
2915
     getpeername(int s, struct sockaddr *name, socklen_t *namelen);
2916
 
2917
DESCRIPTION
2918
     getpeername() returns the address information of the peer connected to
2919
     socket s.  One common use occurs when a process inherits an open socket,
2920
     such as TCP servers forked from inetd(8).  In this scenario,
2921
     getpeername() is used to determine the connecting client's IP address.
2922
 
2923
     getpeername() takes three parameters:
2924
 
2925
     s Contains the file descriptor of the socket whose peer should be looked
2926
     up.
2927
 
2928
     name Points to a sockaddr structure that will hold the address informa-
2929
     tion for the connected peer.  Normal use requires one to use a structure
2930
     specific to the protocol family in use, such as sockaddr_in (IPv4) or
2931
     sockaddr_in6 (IPv6), cast to a (struct sockaddr *).
2932
 
2933
     For greater portability, especially with the newer protocol families, the
2934
     new struct sockaddr_storage should be used.  sockaddr_storage is large
2935
     enough to hold any of the other sockaddr_* variants.  On return, it can
2936
     be cast to the correct sockaddr type, based the protocol family contained
2937
     in its ss_family field.
2938
 
2939
     namelen Indicates the amount of space pointed to by name, in bytes.
2940
 
2941
     If address information for the local end of the socket is required, the
2942
     getsockname(2) function should be used instead.
2943
 
2944
     If name does not point to enough space to hold the entire socket address,
2945
     the result will be truncated to namelen bytes.
2946
 
2947
RETURN VALUES
2948
     If the call succeeds, a 0 is returned and namelen is set to the actual
2949
     size of the socket address returned in name.  Otherwise, errno is set and
2950
     a value of -1 is returned.
2951
 
2952
ERRORS
2953
     On failure, errno is set to one of the following:
2954
 
2955
     [EBADF]            The argument s is not a valid descriptor.
2956
 
2957
     [ENOTSOCK]         The argument s is a file, not a socket.
2958
 
2959
     [ENOTCONN]         The socket is not connected.
2960
 
2961
     [ENOBUFS]          Insufficient resources were available in the system to
2962
                        perform the operation.
2963
 
2964
     [EFAULT]           The name parameter points to memory not in a valid
2965
                        part of the process address space.
2966
 
2967
SEE ALSO
2968
     accept(2), bind(2), getsockname(2), getpeereid(2), socket(2)
2969
 
2970
HISTORY
2971
     The getpeername() function call appeared in 4.2BSD.
2972
 
2973
BSD                              July 17, 1999                             BSD
2974
    
2975
  
2976
 
2977
  
2978
    getsockname
2979
    
2980
GETSOCKNAME(2)                System Calls Manual               GETSOCKNAME(2)
2981
 
2982
NAME
2983
     getsockname - get socket name
2984
 
2985
SYNOPSIS
2986
     #include <sys/types.h>
2987
     #include <sys/socket.h>
2988
 
2989
     int
2990
     getsockname(int s, struct sockaddr *name, socklen_t *namelen);
2991
 
2992
DESCRIPTION
2993
     getsockname() returns the locally bound address information for a speci-
2994
     fied socket.
2995
 
2996
     Common uses of this function are as follows:
2997
 
2998
     o   When bind(2) is called with a port number of 0 (indicating the kernel
2999
         should pick an ephemeral port) getsockname() is used to retrieve the
3000
         kernel-assigned port number.
3001
 
3002
     o   When a process calls bind(2) on a wildcard IP address, getsockname()
3003
         is used to retrieve the local IP address for the connection.
3004
 
3005
     o   When a function wishes to know the address family of a socket,
3006
         getsockname() can be used.
3007
 
3008
     getsockname() takes three parameters:
3009
 
3010
     s, Contains the file desriptor for the socket to be looked up.
3011
 
3012
     name points to a sockaddr structure which will hold the resulting address
3013
     information.  Normal use requires one to use a structure specific to the
3014
     protocol family in use, such as sockaddr_in (IPv4) or sockaddr_in6
3015
     (IPv6), cast to a (struct sockaddr *).
3016
 
3017
     For greater portability (such as newer protocol families) the new struc-
3018
     ture sockaddr_storage exists.  sockaddr_storage is large enough to hold
3019
     any of the other sockaddr_* variants.  On return, it should be cast to
3020
     the correct sockaddr type, according to the current protocol family.
3021
 
3022
     namelen Indicates the amount of space pointed to by name, in bytes.  Upon
3023
     return, namelen is set to the actual size of the returned address infor-
3024
     mation.
3025
 
3026
     If the address of the destination socket for a given socket connection is
3027
     needed, the getpeername(2) function should be used instead.
3028
 
3029
     If name does not point to enough space to hold the entire socket address,
3030
     the result will be truncated to namelen bytes.
3031
 
3032
RETURN VALUES
3033
     On success, getsockname() returns a 0, and namelen is set to the actual
3034
     size of the socket address returned in name.  Otherwise, errno is set,
3035
     and a value of -1 is returned.
3036
 
3037
ERRORS
3038
     If getsockname() fails, errno is set to one of the following:
3039
 
3040
     [EBADF]            The argument s is not a valid descriptor.
3041
 
3042
     [ENOTSOCK]         The argument s is a file, not a socket.
3043
 
3044
     [ENOBUFS]          Insufficient resources were available in the system to
3045
                        perform the operation.
3046
 
3047
     [EFAULT]           The name parameter points to memory not in a valid
3048
                        part of the process address space.
3049
 
3050
SEE ALSO
3051
     accept(2), bind(2), getpeername(2), getpeereid(2), socket(2)
3052
 
3053
BUGS
3054
     Names bound to sockets in the UNIX domain are inaccessible; getsockname
3055
     returns a zero length name.
3056
 
3057
HISTORY
3058
     The getsockname() function call appeared in 4.2BSD.
3059
 
3060
BSD                              July 17, 1999                             BSD
3061
    
3062
  
3063
 
3064
  
3065
    getsockopt
3066
    
3067
GETSOCKOPT(2)                 System Calls Manual                GETSOCKOPT(2)
3068
 
3069
NAME
3070
     getsockopt, setsockopt - get and set options on sockets
3071
 
3072
SYNOPSIS
3073
     #include <sys/types.h>
3074
     #include <sys/socket.h>
3075
 
3076
     int
3077
     getsockopt(int s, int level, int optname, void *optval,
3078
             socklen_t *optlen);
3079
 
3080
     int
3081
     setsockopt(int s, int level, int optname, const void *optval,
3082
             socklen_t optlen);
3083
 
3084
DESCRIPTION
3085
     getsockopt() and setsockopt() manipulate the options associated with a
3086
     socket.  Options may exist at multiple protocol levels; they are always
3087
     present at the uppermost ``socket'' level.
3088
 
3089
     When manipulating socket options the level at which the option resides
3090
     and the name of the option must be specified.  To manipulate options at
3091
     the socket level, level is specified as SOL_SOCKET.  To manipulate
3092
     options at any other level the protocol number of the appropriate proto-
3093
     col controlling the option is supplied.  For example, to indicate that an
3094
     option is to be interpreted by the TCP protocol, level should be set to
3095
     the protocol number of TCP; see getprotoent(3).
3096
 
3097
     The parameters optval and optlen are used to access option values for
3098
     setsockopt().  For getsockopt() they identify a buffer in which the value
3099
     for the requested option(s) are to be returned.  For getsockopt(), optlen
3100
     is a value-result parameter, initially containing the size of the buffer
3101
     pointed to by optval, and modified on return to indicate the actual size
3102
     of the value returned.  If no option value is to be supplied or returned,
3103
     optval may be NULL.
3104
 
3105
     optname and any specified options are passed uninterpreted to the appro-
3106
     priate protocol module for interpretation.  The include file
3107
     <sys/socket.h> contains definitions for socket level options, described
3108
     below.  Options at other protocol levels vary in format and name; consult
3109
     the appropriate entries in section 4 of the manual.
3110
 
3111
     Most socket-level options utilize an int parameter for optval.  For
3112
     setsockopt(), the parameter should be non-zero to enable a boolean
3113
     option, or zero if the option is to be disabled.  SO_LINGER uses a struct
3114
     linger parameter, defined in <sys/socket.h>, which specifies the desired
3115
     state of the option and the linger interval (see below).  SO_SNDTIMEO and
3116
     SO_RCVTIMEO use a struct timeval parameter, defined in <sys/time.h>.
3117
 
3118
     The following options are recognized at the socket level.  Except as
3119
     noted, each may be examined with getsockopt() and set with setsockopt().
3120
 
3121
           SO_DEBUG        enables recording of debugging information
3122
           SO_REUSEADDR    enables local address reuse
3123
           SO_REUSEPORT    enables duplicate address and port bindings
3124
           SO_KEEPALIVE    enables keep connections alive
3125
           SO_DONTROUTE    enables routing bypass for outgoing messages
3126
           SO_LINGER       linger on close if data present
3127
           SO_BROADCAST    enables permission to transmit broadcast messages
3128
           SO_OOBINLINE    enables reception of out-of-band data in band
3129
           SO_SNDBUF       set buffer size for output
3130
           SO_RCVBUF       set buffer size for input
3131
           SO_SNDLOWAT     set minimum count for output
3132
           SO_RCVLOWAT     set minimum count for input
3133
           SO_SNDTIMEO     set timeout value for output
3134
           SO_RCVTIMEO     set timeout value for input
3135
           SO_TYPE         get the type of the socket (get only)
3136
           SO_ERROR        get and clear error on the socket (get only)
3137
 
3138
     SO_DEBUG enables debugging in the underlying protocol modules.
3139
     SO_REUSEADDR indicates that the rules used in validating addresses sup-
3140
     plied in a bind(2) call should allow reuse of local addresses.
3141
     SO_REUSEPORT allows completely duplicate bindings by multiple processes
3142
     if they all set SO_REUSEPORT before binding the port.  This option per-
3143
     mits multiple instances of a program to each receive UDP/IP multicast or
3144
     broadcast datagrams destined for the bound port.  SO_KEEPALIVE enables
3145
     the periodic transmission of messages on a connected socket.  Should the
3146
     connected party fail to respond to these messages, the connection is con-
3147
     sidered broken and processes using the socket are notified via a SIGPIPE
3148
     signal when attempting to send data.  SO_DONTROUTE indicates that outgo-
3149
     ing messages should bypass the standard routing facilities.  Instead,
3150
     messages are directed to the appropriate network interface according to
3151
     the network portion of the destination address.
3152
 
3153
     SO_LINGER controls the action taken when unsent messages are queued on
3154
     socket and a close(2) is performed.  If the socket promises reliable
3155
     delivery of data and SO_LINGER is set, the system will block the process
3156
     on the close(2) attempt until it is able to transmit the data or until it
3157
     decides it is unable to deliver the information (a timeout period mea-
3158
     sured in seconds, termed the linger interval, is specified in the
3159
     setsockopt() call when SO_LINGER is requested).  If SO_LINGER is disabled
3160
     and a close(2) is issued, the system will process the close in a manner
3161
     that allows the process to continue as quickly as possible.
3162
 
3163
     The option SO_BROADCAST requests permission to send broadcast datagrams
3164
     on the socket.  Broadcast was a privileged operation in earlier versions
3165
     of the system.  With protocols that support out-of-band data, the
3166
     SO_OOBINLINE option requests that out-of-band data be placed in the nor-
3167
     mal data input queue as received; it will then be accessible with recv(2)
3168
     or read(2) calls without the MSG_OOB flag.  Some protocols always behave
3169
     as if this option is set.  SO_SNDBUF and SO_RCVBUF are options to adjust
3170
     the normal buffer sizes allocated for output and input buffers, respec-
3171
     tively.  The buffer size may be increased for high-volume connections, or
3172
     may be decreased to limit the possible backlog of incoming data.  The
3173
     system places an absolute limit on these values.
3174
 
3175
     SO_SNDLOWAT is an option to set the minimum count for output operations.
3176
     Most output operations process all of the data supplied by the call,
3177
     delivering data to the protocol for transmission and blocking as neces-
3178
     sary for flow control.  Nonblocking output operations will process as
3179
     much data as permitted subject to flow control without blocking, but will
3180
     process no data if flow control does not allow the smaller of the low
3181
     water mark value or the entire request to be processed.  A select(2) or
3182
     poll(2) operation testing the ability to write to a socket will return
3183
     true only if the low water mark amount could be processed.  The default
3184
     value for SO_SNDLOWAT is set to a convenient size for network efficiency,
3185
     often 1024.  SO_RCVLOWAT is an option to set the minimum count for input
3186
     operations.  In general, receive calls will block until any (non-zero)
3187
     amount of data is received, then return with the smaller of the amount
3188
     available or the amount requested.  The default value for SO_RCVLOWAT is
3189
     1.  If SO_RCVLOWAT is set to a larger value, blocking receive calls nor-
3190
     mally wait until they have received the smaller of the low water mark
3191
     value or the requested amount.  Receive calls may still return less than
3192
     the low water mark if an error occurs, a signal is caught, or the type of
3193
     data next in the receive queue is different than that returned.
3194
 
3195
     SO_SNDTIMEO is an option to set a timeout value for output operations.
3196
     It accepts a struct timeval parameter with the number of seconds and
3197
     microseconds used to limit waits for output operations to complete.  If a
3198
     send operation has blocked for this much time, it returns with a partial
3199
     count or with the error EWOULDBLOCK if no data was sent.  In the current
3200
     implementation, this timer is restarted each time additional data are
3201
     delivered to the protocol, implying that the limit applies to output por-
3202
     tions ranging in size from the low water mark to the high water mark for
3203
     output.  SO_RCVTIMEO is an option to set a timeout value for input opera-
3204
     tions.  It accepts a struct timeval parameter with the number of seconds
3205
     and microseconds used to limit waits for input operations to complete.
3206
     In the current implementation, this timer is restarted each time addi-
3207
     tional data are received by the protocol, and thus the limit is in effect
3208
     an inactivity timer.  If a receive operation has been blocked for this
3209
     much time without receiving additional data, it returns with a short
3210
     count or with the error EWOULDBLOCK if no data were received.
3211
 
3212
     Finally, SO_TYPE and SO_ERROR are options used only with getsockopt().
3213
     SO_TYPE returns the type of the socket, such as SOCK_STREAM; it is useful
3214
     for servers that inherit sockets on startup.  SO_ERROR returns any pend-
3215
     ing error on the socket and clears the error status.  It may be used to
3216
     check for asynchronous errors on connected datagram sockets or for other
3217
     asynchronous errors.
3218
 
3219
RETURN VALUES
3220
     A 0 is returned if the call succeeds, -1 if it fails.
3221
 
3222
ERRORS
3223
     The call succeeds unless:
3224
 
3225
     [EBADF]            The argument s is not a valid descriptor.
3226
 
3227
     [ENOTSOCK]         The argument s is a file, not a socket.
3228
 
3229
     [ENOPROTOOPT]      The option is unknown at the level indicated.
3230
 
3231
     [EFAULT]           The address pointed to by optval is not in a valid
3232
                        part of the process address space.  For getsockopt(),
3233
                        this error may also be returned if optlen is not in a
3234
                        valid part of the process address space.
3235
 
3236
SEE ALSO
3237
     connect(2), ioctl(2), poll(2), select(2), poll(2), socket(2),
3238
     getprotoent(3), protocols(5)
3239
 
3240
BUGS
3241
     Several of the socket options should be handled at lower levels of the
3242
     system.
3243
 
3244
HISTORY
3245
     The getsockopt() system call appeared in 4.2BSD.
3246
 
3247
BSD                            February 15, 1999                           BSD
3248
    
3249
  
3250
 
3251
  
3252
    ioctl
3253
    
3254
IOCTL(2)                      System Calls Manual                     IOCTL(2)
3255
 
3256
NAME
3257
     ioctl - control device
3258
 
3259
SYNOPSIS
3260
     #include <sys/ioctl.h>
3261
 
3262
     int
3263
     ioctl(int d, unsigned long request, ...);
3264
 
3265
DESCRIPTION
3266
     The ioctl() function manipulates the underlying device parameters of spe-
3267
     cial files.  In particular, many operating characteristics of character
3268
     special files (e.g., terminals) may be controlled with ioctl() requests.
3269
 
3270
     The argument d must be an open file descriptor. The third argument is
3271
     called arg and contains additional information needed by this device to
3272
     perform the requested function.  arg is either an int or a pointer to a
3273
     device-specific data structure, depending upon the given request.
3274
 
3275
     An ioctl request has encoded in it whether the argument is an ``in''
3276
     parameter or ``out'' parameter, and the size of the third argument (arg)
3277
     in bytes.  Macros and defines used in specifying an ioctl request are
3278
     located in the file <sys/ioctl.h>.
3279
 
3280
RETURN VALUES
3281
     If an error has occurred, a value of -1 is returned and errno is set to
3282
     indicate the error.
3283
 
3284
ERRORS
3285
     ioctl() will fail if:
3286
 
3287
     [EBADF]            d is not a valid descriptor.
3288
 
3289
     [ENOTTY]           d is not associated with a character special device.
3290
 
3291
     [ENOTTY]           The specified request does not apply to the kind of
3292
                        object that the descriptor d references.
3293
 
3294
     [EINVAL]           request or arg is not valid.
3295
 
3296
     [EFAULT]           arg points outside the process's allocated address
3297
                        space.
3298
 
3299
SEE ALSO
3300
     cdio(1), chio(1), mt(1), execve(2), fcntl(2), intro(4), tty(4)
3301
 
3302
HISTORY
3303
     An ioctl() function call appeared in Version 7 AT&T UNIX.
3304
 
3305
BSD                            December 11, 1993                           BSD
3306
    
3307
  
3308
 
3309
  
3310
    poll
3311
    
3312
POLL(2)                       System Calls Manual                      POLL(2)
3313
 
3314
NAME
3315
     poll - synchronous I/O multiplexing
3316
 
3317
SYNOPSIS
3318
     #include <poll.h>
3319
 
3320
     int
3321
     poll(struct pollfd *fds, int nfds, int timeout);
3322
 
3323
DESCRIPTION
3324
     poll() provides a mechanism for reporting I/O conditions across a set of
3325
     file descriptors.
3326
 
3327
     The arguments are as follows:
3328
 
3329
     fds      Points to an array of pollfd structures, which are defined as:
3330
 
3331
                    struct pollfd {
3332
                            int fd;
3333
                            short events;
3334
                            short revents;
3335
                    };
3336
 
3337
              The fd member is an open file descriptor.  The events and
3338
              revents members are bitmasks of conditions to monitor and condi-
3339
              tions found, respectively.
3340
 
3341
     nfds     The number of pollfd structures in the array.
3342
 
3343
     timeout  Maximum interval to wait for the poll to complete, in millisec-
3344
              onds.  If this value is 0, then poll() will return immediately.
3345
              If this value is INFTIM (-1), poll() will block indefinitely
3346
              until a condition is found.
3347
 
3348
     The calling process sets the events bitmask and poll() sets the revents
3349
     bitmask.  Each call to poll() resets the revents bitmask for accuracy.
3350
     The condition flags in the bitmasks are defined as:
3351
 
3352
     POLLIN      Data is available on the file descriptor for reading.
3353
 
3354
     POLLNORM    Same as POLLIN.
3355
 
3356
     POLLPRI     Same as POLLIN.
3357
 
3358
     POLLOUT     Data can be written to the file descriptor without blocking.
3359
 
3360
     POLLERR     This flag is not used in this implementation and is provided
3361
                 only for source code compatibility.
3362
 
3363
     POLLHUP     The file descriptor was valid before the polling process and
3364
                 invalid after.  Presumably, this means that the file descrip-
3365
                 tor was closed sometime during the poll.
3366
 
3367
     POLLNVAL    The corresponding file descriptor is invalid.
3368
 
3369
     POLLRDNORM  Same as POLLIN.
3370
 
3371
     POLLRDBAND  Same as POLLIN.
3372
 
3373
     POLLWRNORM  Same as POLLOUT.
3374
 
3375
     POLLWRBAND  Same as POLLOUT.
3376
 
3377
     POLLMSG     This flag is not used in this implementation and is provided
3378
                 only for source code compatibility.
3379
 
3380
     All flags except POLLIN, POLLOUT, and their synonyms are for use only in
3381
     the revents member of the pollfd structure.  An attempt to set any of
3382
     these flags in the events member will generate an error condition.
3383
 
3384
     In addition to I/O multiplexing, poll() can be used to generate simple
3385
     timeouts.  This functionality may be achieved by passing a null pointer
3386
     for fds.
3387
 
3388
WARNINGS
3389
     The POLLHUP flag is only a close approximation and may not always be
3390
     accurate.
3391
 
3392
RETURN VALUES
3393
     Upon error, poll() returns a -1 and sets the global variable errno to
3394
     indicate the error.  If the timeout interval was reached before any
3395
     events occurred, a 0 is returned.  Otherwise, poll() returns the number
3396
     of file descriptors for which revents is non-zero.
3397
 
3398
ERRORS
3399
     poll() will fail if:
3400
 
3401
     [EINVAL]   nfds was either a negative number or greater than the number
3402
                of available file descriptors.
3403
 
3404
     [EINVAL]   An invalid flags was set in the events member of the pollfd
3405
                structure.
3406
 
3407
     [EINVAL]   The timeout passed to poll() was too large.
3408
 
3409
     [EAGAIN]   Resource allocation failed inside of poll().  Subsequent calls
3410
                to poll() may succeed.
3411
 
3412
     [EINTR]    poll() caught a signal during the polling process.
3413
 
3414
SEE ALSO
3415
     poll(2), select(2), sysconf(3)
3416
 
3417
HISTORY
3418
     A poll() system call appeared in AT&T System V UNIX.
3419
 
3420
BSD                            December 13, 1994                           BSD
3421
    
3422
  
3423
 
3424
  
3425
    select
3426
    
3427
SELECT(2)                     System Calls Manual                    SELECT(2)
3428
 
3429
NAME
3430
     select - synchronous I/O multiplexing
3431
 
3432
SYNOPSIS
3433
     #include <sys/types.h>
3434
     #include <sys/time.h>
3435
     #include <unistd.h>
3436
 
3437
     int
3438
     select(int nfds, fd_set *readfds, fd_set *writefds, fd_set *exceptfds,
3439
             struct timeval *timeout);
3440
 
3441
     FD_SET(fd, &fdset);
3442
 
3443
     FD_CLR(fd, &fdset);
3444
 
3445
     FD_ISSET(fd, &fdset);
3446
 
3447
     FD_ZERO(&fdset);
3448
 
3449
DESCRIPTION
3450
     select() examines the I/O descriptor sets whose addresses are passed in
3451
     readfds, writefds, and exceptfds to see if some of their descriptors are
3452
     ready for reading, are ready for writing, or have an exceptional condi-
3453
     tion pending, respectively.  The first nfds descriptors are checked in
3454
     each set; i.e., the descriptors from 0 through nfds-1 in the descriptor
3455
     sets are examined.  On return, select() replaces the given descriptor
3456
     sets with subsets consisting of those descriptors that are ready for the
3457
     requested operation.  select() returns the total number of ready descrip-
3458
     tors in all the sets.
3459
 
3460
     The descriptor sets are stored as bit fields in arrays of integers.  The
3461
     following macros are provided for manipulating such descriptor sets:
3462
     FD_ZERO(&fdset) initializes a descriptor set fdset to the null set.
3463
     FD_SET(fd, &fdset) includes a particular descriptor fd in fdset.
3464
     FD_CLR(fd, &fdset) removes fd from fdset.  FD_ISSET(fd, &fdset) is non-
3465
     zero if fd is a member of fdset, zero otherwise.  The behavior of these
3466
     macros is undefined if a descriptor value is less than zero or greater
3467
     than or equal to FD_SETSIZE, which is normally at least equal to the max-
3468
     imum number of descriptors supported by the system.
3469
 
3470
     If timeout is a non-null pointer, it specifies a maximum interval to wait
3471
     for the selection to complete.  If timeout is a null pointer, the select
3472
     blocks indefinitely.  To effect a poll, the timeout argument should be
3473
     non-null, pointing to a zero-valued timeval structure.  timeout is not
3474
     changed by select(), and may be reused on subsequent calls; however, it
3475
     is good style to re-initialize it before each invocation of select().
3476
 
3477
     Any of readfds, writefds, and exceptfds may be given as null pointers if
3478
     no descriptors are of interest.
3479
 
3480
RETURN VALUES
3481
     select() returns the number of ready descriptors that are contained in
3482
     the descriptor sets, or -1 is an error occurred.  If the time limit
3483
     expires, select() returns 0.  If select() returns with an error, includ-
3484
     ing one due to an interrupted call, the descriptor sets will be unmodi-
3485
     fied.
3486
 
3487
ERRORS
3488
     An error return from select() indicates:
3489
 
3490
     [EFAULT]           One or more of readfds, writefds, or exceptfds points
3491
                        outside the process's allocated address space.
3492
 
3493
     [EBADF]            One of the descriptor sets specified an invalid
3494
                        descriptor.
3495
 
3496
     [EINTR]            A signal was delivered before the time limit expired
3497
                        and before any of the selected events occurred.
3498
 
3499
     [EINVAL]           The specified time limit is invalid.  One of its com-
3500
                        ponents is negative or too large.
3501
 
3502
SEE ALSO
3503
     accept(2), connect(2), gettimeofday(2), poll(2), read(2), recv(2),
3504
     send(2), write(2), getdtablesize(3)
3505
 
3506
BUGS
3507
     Although the provision of getdtablesize(3) was intended to allow user
3508
     programs to be written independent of the kernel limit on the number of
3509
     open files, the dimension of a sufficiently large bit field for select
3510
     remains a problem.  The default bit size of fd_set is based on the symbol
3511
     FD_SETSIZE (currently 256), but that is somewhat smaller than the current
3512
     kernel limit to the number of open files.  However, in order to accommo-
3513
     date programs which might potentially use a larger number of open files
3514
     with select, it is possible to increase this size within a program by
3515
     providing a larger definition of FD_SETSIZE before the inclusion of
3516
     <sys/types.h>.  The kernel will cope, and the userland libraries provided
3517
     with the system are also ready for large numbers of file descriptors.
3518
 
3519
     Alternatively, to be really safe, it is possible to allocate fd_set bit-
3520
     arrays dynamically.  The idea is to permit a program to work properly
3521
     even if it is execve(2)'d with 4000 file descriptors pre-allocated.  The
3522
     following illustrates the technique which is used by userland libraries:
3523
 
3524
                   fd_set *fdsr;
3525
                   int max = fd;
3526
 
3527
                   fdsr = (fd_set *)calloc(howmany(max+1, NFDBITS),
3528
                       sizeof(fd_mask));
3529
                   if (fdsr == NULL) {
3530
                           ...
3531
                           return (-1);
3532
                   }
3533
                   FD_SET(fd, fdsr);
3534
                   n = select(max+1, fdsr, NULL, NULL, &tv);
3535
                   ...
3536
                   free(fdsr);
3537
 
3538
     Alternatively, it is possible to use the poll(2) interface.  poll(2) is
3539
     more efficient when the size of select()'s fd_set bit-arrays are very
3540
     large, and for fixed numbers of file descriptors one need not size and
3541
     dynamically allocate a memory object.
3542
 
3543
     select() should probably have been designed to return the time remaining
3544
     from the original timeout, if any, by modifying the time value in place.
3545
     Even though some systems stupidly act in this different way, it is
3546
     unlikely this semantic will ever be commonly implemented, as the change
3547
     causes massive source code compatibility problems.  Furthermore, recent
3548
     new standards have dictated the current behaviour.  In general, due to
3549
     the existence of those brain-damaged non-conforming systems, it is unwise
3550
     to assume that the timeout value will be unmodified by the select() call,
3551
     and the caller should reinitialize it on each invocation.  Calculating
3552
     the delta is easily done by calling gettimeofday(2) before and after the
3553
     call to select(), and using timersub() (as described in getitimer(2)).
3554
 
3555
     Internally to the kernel, select() works poorly if multiple processes
3556
     wait on the same file descriptor.  Given that, it is rather surprising to
3557
     see that many daemons are written that way (i.e., httpd(8)).
3558
 
3559
HISTORY
3560
     The select() function call appeared in 4.2BSD.
3561
 
3562
BSD                             March 25, 1994                             BSD
3563
    
3564
  
3565
 
3566
  
3567
    send
3568
    
3569
SEND(2)                       System Calls Manual                      SEND(2)
3570
 
3571
NAME
3572
     send, sendto, sendmsg - send a message from a socket
3573
 
3574
SYNOPSIS
3575
     #include <sys/types.h>
3576
     #include <sys/socket.h>
3577
 
3578
     ssize_t
3579
     send(int s, const void *msg, size_t len, int flags);
3580
 
3581
     ssize_t
3582
     sendto(int s, const void *msg, size_t len, int flags,
3583
             const struct sockaddr *to, socklen_t tolen);
3584
 
3585
     ssize_t
3586
     sendmsg(int s, const struct msghdr *msg, int flags);
3587
 
3588
DESCRIPTION
3589
     send(), sendto(), and sendmsg() are used to transmit a message to another
3590
     socket.  send() may be used only when the socket is in a connected state,
3591
     while sendto() and sendmsg() may be used at any time.
3592
 
3593
     The address of the target is given by to with tolen specifying its size.
3594
     The length of the message is given by len.  If the message is too long to
3595
     pass atomically through the underlying protocol, the error EMSGSIZE is
3596
     returned, and the message is not transmitted.
3597
 
3598
     No indication of failure to deliver is implicit in a send().  Locally
3599
     detected errors are indicated by a return value of -1.
3600
 
3601
     If no messages space is available at the socket to hold the message to be
3602
     transmitted, then send() normally blocks, unless the socket has been
3603
     placed in non-blocking I/O mode.  The select(2) or poll(2) system calls
3604
     may be used to determine when it is possible to send more data.
3605
 
3606
     The flags parameter may include one or more of the following:
3607
 
3608
     #define MSG_OOB        0x1  /* process out-of-band data */
3609
     #define MSG_DONTROUTE  0x4  /* bypass routing, use direct interface */
3610
 
3611
     The flag MSG_OOB is used to send ``out-of-band'' data on sockets that
3612
     support this notion (e.g., SOCK_STREAM); the underlying protocol must
3613
     also support ``out-of-band'' data.  MSG_DONTROUTE is usually used only by
3614
     diagnostic or routing programs.
3615
 
3616
     See recv(2) for a description of the msghdr structure.
3617
 
3618
RETURN VALUES
3619
     The call returns the number of characters sent, or -1 if an error
3620
     occurred.
3621
 
3622
ERRORS
3623
     send(), sendto(), and sendmsg() fail if:
3624
 
3625
     [EBADF]            An invalid descriptor was specified.
3626
 
3627
     [ENOTSOCK]         The argument s is not a socket.
3628
 
3629
     [EFAULT]           An invalid user space address was specified for a
3630
                        parameter.
3631
 
3632
     [EMSGSIZE]         The socket requires that message be sent atomically,
3633
                        and the size of the message to be sent made this
3634
                        impossible.
3635
 
3636
     [EAGAIN]           The socket is marked non-blocking and the requested
3637
                        operation would block.
3638
 
3639
     [ENOBUFS]          The system was unable to allocate an internal buffer.
3640
                        The operation may succeed when buffers become avail-
3641
                        able.
3642
 
3643
     [ENOBUFS]          The output queue for a network interface was full.
3644
                        This generally indicates that the interface has
3645
                        stopped sending, but may be caused by transient con-
3646
                        gestion.
3647
 
3648
     [EACCES]           The SO_BROADCAST option is not set on the socket, and
3649
                        a broadcast address was given as the destination.
3650
 
3651
     [EHOSTUNREACH]     The destination address specified an unreachable host.
3652
 
3653
     [EINVAL]           The flags parameter is invalid.
3654
 
3655
     [EHOSTDOWN]        The destination address specified a host that is down.
3656
 
3657
     [ENETDOWN]         The destination address specified a network that is
3658
                        down.
3659
 
3660
     [ECONNREFUSED]     The destination host rejected the message (or a previ-
3661
                        ous one).  This error can only be returned by con-
3662
                        nected sockets.
3663
 
3664
     [ENOPROTOOPT]      There was a problem sending the message.  This error
3665
                        can only be returned by connected sockets.
3666
 
3667
     [EDESTADDRREQ]     The socket is not connected, and no destination
3668
                        address was specified.
3669
 
3670
     [EISCONN]          The socket is already connected, and a destination
3671
                        address was specified.
3672
 
3673
     In addition, send() and sendto() may return the following error:
3674
 
3675
     [EINVAL]           len was larger than SSIZE_MAX.
3676
 
3677
     Also, sendmsg() may return the following errors:
3678
 
3679
     [EINVAL]           The sum of the iov_len values in the msg_iov array
3680
                        overflowed an ssize_t.
3681
 
3682
     [EMSGSIZE]         The msg_iovlen member of msg was less than 0 or larger
3683
                        than IOV_MAX.
3684
 
3685
     [EAFNOSUPPORT]     Addresses in the specified address family cannot be
3686
                        used with this socket.
3687
 
3688
SEE ALSO
3689
     fcntl(2), getsockopt(2), poll(2), recv(2), select(2), poll(2), socket(2),
3690
     write(2)
3691
 
3692
HISTORY
3693
     The send() function call appeared in 4.2BSD.
3694
 
3695
BSD                              July 28, 1998                             BSD
3696
    
3697
  
3698
 
3699
  
3700
    shutdown
3701
    
3702
SHUTDOWN(2)                   System Calls Manual                  SHUTDOWN(2)
3703
 
3704
NAME
3705
     shutdown - shut down part of a full-duplex connection
3706
 
3707
SYNOPSIS
3708
     #include <sys/types.h>
3709
     #include <sys/socket.h>
3710
 
3711
     int
3712
     shutdown(int s, int how);
3713
 
3714
DESCRIPTION
3715
     The shutdown() call causes all or part of a full-duplex connection on the
3716
     socket associated with s to be shut down.  If how is SHUT_RD, further
3717
     receives will be disallowed.  If how is SHUT_WR, further sends will be
3718
     disallowed.  If how is SHUT_RDWR, further sends and receives will be dis-
3719
     allowed.
3720
 
3721
RETURN VALUES
3722
     A 0 is returned if the call succeeds, -1 if it fails.
3723
 
3724
ERRORS
3725
     The call succeeds unless:
3726
 
3727
     [EINVAL]           how is not SHUT_RD, SHUT_WR, or SHUT_RDWR.
3728
 
3729
     [EBADF]            s is not a valid descriptor.
3730
 
3731
     [ENOTSOCK]         s is a file, not a socket.
3732
 
3733
     [ENOTCONN]         The specified socket is not connected.
3734
 
3735
SEE ALSO
3736
     connect(2), socket(2)
3737
 
3738
HISTORY
3739
     The shutdown() function call appeared in 4.2BSD.  The how arguments used
3740
     to be simply 0, 1, and 2, but now have named values as specified by
3741
     X/Open Portability Guide Issue 4 (``XPG4'').
3742
 
3743
BSD                              June 4, 1993                              BSD
3744
    
3745
  
3746
 
3747
  
3748
    socket
3749
    
3750
SOCKET(2)                     System Calls Manual                    SOCKET(2)
3751
 
3752
NAME
3753
     socket - create an endpoint for communication
3754
 
3755
SYNOPSIS
3756
     #include <sys/types.h>
3757
     #include <sys/socket.h>
3758
 
3759
     int
3760
     socket(int domain, int type, int protocol);
3761
 
3762
DESCRIPTION
3763
     socket() creates an endpoint for communication and returns a descriptor.
3764
 
3765
     The domain parameter specifies a communications domain within which com-
3766
     munication will take place; this selects the protocol family which should
3767
     be used.  These families are defined in the include file <sys/socket.h>.
3768
     The currently understood formats are
3769
 
3770
           AF_UNIX         (UNIX internal protocols),
3771
           AF_INET         (ARPA Internet protocols),
3772
           AF_INET6        (ARPA IPv6 protocols),
3773
           AF_ISO          (ISO protocols),
3774
           AF_NS           (Xerox Network Systems protocols),
3775
           AF_IPX          (Internetwork Packet Exchange), and
3776
           AF_IMPLINK      (IMP host at IMP link layer).
3777
 
3778
     The socket has the indicated type, which specifies the semantics of com-
3779
     munication.  Currently defined types are:
3780
 
3781
           SOCK_STREAM
3782
           SOCK_DGRAM
3783
           SOCK_RAW
3784
           SOCK_SEQPACKET
3785
           SOCK_RDM
3786
 
3787
     A SOCK_STREAM type provides sequenced, reliable, two-way connection based
3788
     byte streams.  An out-of-band data transmission mechanism may be sup-
3789
     ported.  A SOCK_DGRAM socket supports datagrams (connectionless, unreli-
3790
     able messages of a fixed (typically small) maximum length).  A
3791
     SOCK_SEQPACKET socket may provide a sequenced, reliable, two-way connec-
3792
     tion-based data transmission path for datagrams of fixed maximum length;
3793
     a consumer may be required to read an entire packet with each read system
3794
     call.  This facility is protocol specific, and presently implemented only
3795
     for PF_NS.  SOCK_RAW sockets provide access to internal network protocols
3796
     and interfaces.  The types SOCK_RAW, which is available only to the supe-
3797
     ruser, and SOCK_RDM, which is planned, but not yet implemented, are not
3798
     described here.
3799
 
3800
     The protocol specifies a particular protocol to be used with the socket.
3801
     Normally only a single protocol exists to support a particular socket
3802
     type within a given protocol family.  However, it is possible that many
3803
     protocols may exist, in which case a particular protocol must be speci-
3804
     fied in this manner.  The protocol number to use is particular to the
3805
     communication domain in which communication is to take place; see
3806
     protocols(5).  A value of 0 for protocol will let the system select an
3807
     appropriate protocol for the requested socket type.
3808
 
3809
     Sockets of type SOCK_STREAM are full-duplex byte streams, similar to
3810
     pipes.  A stream socket must be in a connected state before any data may
3811
     be sent or received on it.  A connection to another socket is created
3812
     with a connect(2) call.  Once connected, data may be transferred using
3813
     read(2) and write(2) calls or some variant of the send(2) and recv(2)
3814
     calls.  When a session has been completed a close(2) may be performed.
3815
     Out-of-band data may also be transmitted as described in send(2) and
3816
     received as described in recv(2).
3817
 
3818
     The communications protocols used to implement a SOCK_STREAM ensure that
3819
     data is not lost or duplicated.  If a piece of data for which the peer
3820
     protocol has buffer space cannot be successfully transmitted within a
3821
     reasonable length of time, then the connection is considered broken and
3822
     calls will indicate an error with -1 returns and with ETIMEDOUT as the
3823
     specific code in the global variable errno.  The protocols optionally
3824
     keep sockets ``warm'' by forcing transmissions roughly every minute in
3825
     the absence of other activity.  An error is then indicated if no response
3826
     can be elicited on an otherwise idle connection for a extended period
3827
     (e.g., 5 minutes).  A SIGPIPE signal is raised if a process sends on a
3828
     broken stream; this causes naive processes, which do not handle the sig-
3829
     nal, to exit.
3830
 
3831
     SOCK_SEQPACKET sockets employ the same system calls as SOCK_STREAM sock-
3832
     ets.  The only difference is that read(2) calls will return only the
3833
     amount of data requested, and any remaining in the arriving packet will
3834
     be discarded.
3835
 
3836
     SOCK_DGRAM and SOCK_RAW sockets allow sending of datagrams to correspon-
3837
     dents named in send(2) calls.  Datagrams are generally received with
3838
     recvfrom(2), which returns the next datagram with its return address.
3839
 
3840
     An fcntl(2) call can be used to specify a process group to receive a
3841
     SIGURG signal when the out-of-band data arrives.  It may also enable non-
3842
     blocking I/O and asynchronous notification of I/O events via SIGIO.
3843
 
3844
     The operation of sockets is controlled by socket level options.  These
3845
     options are defined in the file <sys/socket.h>.  setsockopt(2) and
3846
     getsockopt(2) are used to set and get options, respectively.
3847
 
3848
RETURN VALUES
3849
     A -1 is returned if an error occurs, otherwise the return value is a
3850
     descriptor referencing the socket.
3851
 
3852
ERRORS
3853
     The socket() call fails if:
3854
 
3855
     [EPROTONOSUPPORT]  The protocol type or the specified protocol is not
3856
                        supported within this domain.
3857
 
3858
     [EMFILE]           The per-process descriptor table is full.
3859
 
3860
     [ENFILE]           The system file table is full.
3861
 
3862
     [EACCES]           Permission to create a socket of the specified type
3863
                        and/or protocol is denied.
3864
 
3865
     [ENOBUFS]          Insufficient buffer space is available.  The socket
3866
                        cannot be created until sufficient resources are
3867
                        freed.
3868
 
3869
SEE ALSO
3870
     accept(2), bind(2), connect(2), getsockname(2), getsockopt(2), ioctl(2),
3871
     listen(2), poll(2), read(2), recv(2), select(2), send(2), setsockopt(2),
3872
     shutdown(2), socketpair(2), write(2), getprotoent(3), netintro(4)
3873
 
3874
     An Introductory 4.3 BSD Interprocess Communication Tutorial, reprinted in
3875
     UNIX Programmer's Supplementary Documents Volume 1.
3876
 
3877
     BSD Interprocess Communication Tutorial, reprinted in UNIX Programmer's
3878
     Supplementary Documents Volume 1.
3879
 
3880
HISTORY
3881
     The socket() function call appeared in 4.2BSD.
3882
 
3883
BSD                              June 4, 1993                              BSD
3884
    
3885
  
3886
 
3887
  
3888
    socketpair
3889
    
3890
SOCKETPAIR(2)                 System Calls Manual                SOCKETPAIR(2)
3891
 
3892
NAME
3893
     socketpair - create a pair of connected sockets
3894
 
3895
SYNOPSIS
3896
     #include <sys/types.h>
3897
     #include <sys/socket.h>
3898
 
3899
     int
3900
     socketpair(int d, int type, int protocol, int *sv);
3901
 
3902
DESCRIPTION
3903
     The socketpair() call creates an unnamed pair of connected sockets in the
3904
     specified domain d, of the specified type, and using the optionally spec-
3905
     ified protocol.  The descriptors used in referencing the new sockets are
3906
     returned in sv[0] and sv[1].  The two sockets are indistinguishable.
3907
 
3908
RETURN VALUES
3909
     A 0 is returned if the call succeeds, -1 if it fails.
3910
 
3911
ERRORS
3912
     The call succeeds unless:
3913
 
3914
     [EMFILE]           Too many descriptors are in use by this process.
3915
 
3916
     [EAFNOSUPPORT]     The specified address family is not supported on this
3917
                        machine.
3918
 
3919
     [EPROTONOSUPPORT]  The specified protocol is not supported on this
3920
                        machine.
3921
 
3922
     [EOPNOTSUPP]       The specified protocol does not support creation of
3923
                        socket pairs.
3924
 
3925
     [EFAULT]           The address sv does not specify a valid part of the
3926
                        process address space.
3927
 
3928
     [ENFILE]           The system file table is full.
3929
 
3930
SEE ALSO
3931
     pipe(2), read(2), write(2)
3932
 
3933
BUGS
3934
     This call is currently implemented only for the LOCAL domain.  Many oper-
3935
     ating systems only accept a protocol of PF_UNSPEC, so that should be used
3936
     instead of PF_LOCAL for maximal portability.
3937
 
3938
STANDARDS
3939
     The socketpair() function conforms to X/Open Portability Guide Issue 4.2
3940
     (``XPG4.2'').
3941
 
3942
HISTORY
3943
     The socketpair() function call appeared in 4.2BSD.
3944
 
3945
BSD                              June 4, 1993                              BSD
3946
    
3947
  
3948
 
3949
 
3950
3951
 
3952
3970
 

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