xref: /freebsd/share/man/man4/netintro.4 (revision 1c05a6ea6b849ff95e539c31adea887c644a6a01)
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31.Dd January 26, 2012
32.Dt NETINTRO 4
33.Os
34.Sh NAME
35.Nm networking
36.Nd introduction to networking facilities
37.Sh SYNOPSIS
38.In sys/types.h
39.In sys/time.h
40.In sys/socket.h
41.In net/if.h
42.In net/route.h
43.Sh DESCRIPTION
44This section is a general introduction to the networking facilities
45available in the system.
46Documentation in this part of section
474 is broken up into three areas:
48.Em protocol families
49(domains),
50.Em protocols ,
51and
52.Em network interfaces .
53.Pp
54All network protocols are associated with a specific
55.Em protocol family .
56A protocol family provides basic services to the protocol
57implementation to allow it to function within a specific
58network environment.
59These services may include
60packet fragmentation and reassembly, routing, addressing, and
61basic transport.
62A protocol family may support multiple
63methods of addressing, though the current protocol implementations
64do not.
65A protocol family is normally comprised of a number of protocols, one per
66.Xr socket 2
67type.
68It is not required that a protocol family support all socket types.
69A protocol family may contain multiple
70protocols supporting the same socket abstraction.
71.Pp
72A protocol supports one of the socket abstractions detailed in
73.Xr socket 2 .
74A specific protocol may be accessed either by creating a
75socket of the appropriate type and protocol family, or
76by requesting the protocol explicitly when creating a socket.
77Protocols normally accept only one type of address format,
78usually determined by the addressing structure inherent in
79the design of the protocol family/network architecture.
80Certain semantics of the basic socket abstractions are
81protocol specific.
82All protocols are expected to support
83the basic model for their particular socket type, but may,
84in addition, provide non-standard facilities or extensions
85to a mechanism.
86For example, a protocol supporting the
87.Dv SOCK_STREAM
88abstraction may allow more than one byte of out-of-band
89data to be transmitted per out-of-band message.
90.Pp
91A network interface is similar to a device interface.
92Network interfaces comprise the lowest layer of the
93networking subsystem, interacting with the actual transport
94hardware.
95An interface may support one or more protocol families and/or address formats.
96The SYNOPSIS section of each network interface
97entry gives a sample specification
98of the related drivers for use in providing
99a system description to the
100.Xr config 8
101program.
102The DIAGNOSTICS section lists messages which may appear on the console
103and/or in the system error log,
104.Pa /var/log/messages
105(see
106.Xr syslogd 8 ) ,
107due to errors in device operation.
108.Sh PROTOCOLS
109The system currently supports the
110Internet
111protocols, the Xerox Network Systems(tm) protocols,
112and some of the
113.Tn ISO OSI
114protocols.
115Raw socket interfaces are provided to the
116.Tn IP
117protocol
118layer of the
119Internet, and to the
120.Tn IDP
121protocol of Xerox
122.Tn NS .
123Consult the appropriate manual pages in this section for more
124information regarding the support for each protocol family.
125.Sh ADDRESSING
126Associated with each protocol family is an address
127format.
128All network addresses adhere to a general structure,
129called a sockaddr, described below.
130However, each protocol
131imposes finer and more specific structure, generally renaming
132the variant, which is discussed in the protocol family manual
133page alluded to above.
134.Bd -literal -offset indent
135struct sockaddr {
136    u_char	sa_len;
137    u_char	sa_family;
138    char	sa_data[14];
139};
140.Ed
141.Pp
142The field
143.Va sa_len
144contains the total length of the structure,
145which may exceed 16 bytes.
146The following address values for
147.Va sa_family
148are known to the system
149(and additional formats are defined for possible future implementation):
150.Bd -literal
151#define    AF_UNIX      1    /* local to host (pipes, portals) */
152#define    AF_INET      2    /* internetwork: UDP, TCP, etc. */
153#define    AF_NS        6    /* Xerox NS protocols */
154#define    AF_CCITT     10   /* CCITT protocols, X.25 etc */
155#define    AF_HYLINK    15   /* NSC Hyperchannel */
156#define    AF_ISO       18   /* ISO protocols */
157.Ed
158.Sh ROUTING
159.Fx
160provides some packet routing facilities.
161The kernel maintains a routing information database, which
162is used in selecting the appropriate network interface when
163transmitting packets.
164.Pp
165A user process (or possibly multiple co-operating processes)
166maintains this database by sending messages over a special kind
167of socket.
168This supplants fixed size
169.Xr ioctl 2
170used in earlier releases.
171.Pp
172This facility is described in
173.Xr route 4 .
174.Sh INTERFACES
175Each network interface in a system corresponds to a
176path through which messages may be sent and received.
177A network interface usually has a hardware device associated with it, though
178certain interfaces such as the loopback interface,
179.Xr lo 4 ,
180do not.
181.Pp
182The following
183.Xr ioctl 2
184calls may be used to manipulate network interfaces.
185The
186.Fn ioctl
187is made on a socket (typically of type
188.Dv SOCK_DGRAM )
189in the desired domain.
190Most of the requests supported in earlier releases
191take an
192.Vt ifreq
193structure as its parameter.
194This structure has the form
195.Bd -literal
196struct	ifreq {
197#define    IFNAMSIZ    16
198    char    ifr_name[IFNAMSIZ];        /* if name, e.g. "en0" */
199    union {
200        struct    sockaddr ifru_addr;
201        struct    sockaddr ifru_dstaddr;
202        struct    sockaddr ifru_broadaddr;
203        struct    ifreq_buffer ifru_buffer;
204        short     ifru_flags[2];
205        short     ifru_index;
206        int       ifru_metric;
207        int       ifru_mtu;
208        int       ifru_phys;
209        int       ifru_media;
210        caddr_t   ifru_data;
211        int       ifru_cap[2];
212    } ifr_ifru;
213#define ifr_addr      ifr_ifru.ifru_addr      /* address */
214#define ifr_dstaddr   ifr_ifru.ifru_dstaddr   /* other end of p-to-p link */
215#define ifr_broadaddr ifr_ifru.ifru_broadaddr /* broadcast address */
216#define ifr_buffer    ifr_ifru.ifru_buffer    /* user supplied buffer with its length */
217#define ifr_flags     ifr_ifru.ifru_flags[0]  /* flags (low 16 bits) */
218#define ifr_flagshigh ifr_ifru.ifru_flags[1]  /* flags (high 16 bits) */
219#define ifr_metric    ifr_ifru.ifru_metric    /* metric */
220#define ifr_mtu       ifr_ifru.ifru_mtu       /* mtu */
221#define ifr_phys      ifr_ifru.ifru_phys      /* physical wire */
222#define ifr_media     ifr_ifru.ifru_media     /* physical media */
223#define ifr_data      ifr_ifru.ifru_data      /* for use by interface */
224#define ifr_reqcap    ifr_ifru.ifru_cap[0]    /* requested capabilities */
225#define ifr_curcap    ifr_ifru.ifru_cap[1]    /* current capabilities */
226#define ifr_index     ifr_ifru.ifru_index     /* interface index */
227};
228.Ed
229.Pp
230.Fn Ioctl
231requests to obtain addresses and requests both to set and
232retrieve other data are still fully supported
233and use the
234.Vt ifreq
235structure:
236.Bl -tag -width SIOCGIFBRDADDR
237.It Dv SIOCGIFADDR
238Get interface address for protocol family.
239.It Dv SIOCGIFDSTADDR
240Get point to point address for protocol family and interface.
241.It Dv SIOCGIFBRDADDR
242Get broadcast address for protocol family and interface.
243.It Dv SIOCSIFCAP
244Attempt to set the enabled capabilities field for the interface
245to the value of the
246.Va ifr_reqcap
247field of the
248.Vt ifreq
249structure.
250Note that, depending on the particular interface features,
251some capabilities may appear hard-coded to enabled, or toggling
252a capability may affect the status of other ones.
253The supported capabilities field is read-only, and the
254.Va ifr_curcap
255field is unused by this call.
256.It Dv SIOCGIFCAP
257Get the interface capabilities fields.
258The values for supported and enabled capabilities will be returned in the
259.Va ifr_reqcap
260and
261.Va ifr_curcap
262fields of the
263.Vt ifreq
264structure, respectively.
265.It Dv SIOCGIFDESCR
266Get the interface description, returned in the
267.Va buffer
268field of
269.Va ifru_buffer
270struct.
271The user supplied buffer length should be defined in the
272.Va length
273field of
274.Va ifru_buffer
275struct passed in as parameter, and the length would include
276the terminating nul character.
277If there is not enough space to hold the interface length,
278no copy would be done and the
279.Va buffer
280field of
281.Va ifru_buffer
282would be set to NULL.
283The kernel will store the buffer length in the
284.Va length
285field upon return, regardless whether the buffer itself is
286sufficient to hold the data.
287.It Dv SIOCSIFDESCR
288Set the interface description to the value of the
289.Va buffer
290field of
291.Va ifru_buffer
292struct, with
293.Va length
294field specifying its length (counting the terminating nul).
295.It Dv SIOCSIFFLAGS
296Set interface flags field.
297If the interface is marked down,
298any processes currently routing packets through the interface
299are notified;
300some interfaces may be reset so that incoming packets are no longer received.
301When marked up again, the interface is reinitialized.
302.It Dv SIOCGIFFLAGS
303Get interface flags.
304.It Dv SIOCSIFMETRIC
305Set interface routing metric.
306The metric is used only by user-level routers.
307.It Dv SIOCGIFMETRIC
308Get interface metric.
309.It Dv SIOCIFCREATE
310Attempt to create the specified interface.
311If the interface name is given without a unit number the system
312will attempt to create a new interface with an arbitrary unit number.
313On successful return the
314.Va ifr_name
315field will contain the new interface name.
316.It Dv SIOCIFDESTROY
317Attempt to destroy the specified interface.
318.El
319.Pp
320There are two requests that make use of a new structure:
321.Bl -tag -width SIOCGIFBRDADDR
322.It Dv SIOCAIFADDR
323An interface may have more than one address associated with it
324in some protocols.
325This request provides a means to
326add additional addresses (or modify characteristics of the
327primary address if the default address for the address family
328is specified).
329Rather than making separate calls to
330set destination or broadcast addresses, or network masks
331(now an integral feature of multiple protocols)
332a separate structure is used to specify all three facets simultaneously
333(see below).
334One would use a slightly tailored version of this struct specific
335to each family (replacing each sockaddr by one
336of the family-specific type).
337Where the sockaddr itself is larger than the
338default size, one needs to modify the
339.Fn ioctl
340identifier itself to include the total size, as described in
341.Fn ioctl .
342.It Dv SIOCDIFADDR
343This requests deletes the specified address from the list
344associated with an interface.
345It also uses the
346.Vt ifaliasreq
347structure to allow for the possibility of protocols allowing
348multiple masks or destination addresses, and also adopts the
349convention that specification of the default address means
350to delete the first address for the interface belonging to
351the address family in which the original socket was opened.
352.It Dv SIOCGIFCONF
353Get interface configuration list.
354This request takes an
355.Vt ifconf
356structure (see below) as a value-result parameter.
357The
358.Va ifc_len
359field should be initially set to the size of the buffer
360pointed to by
361.Va ifc_buf .
362On return it will contain the length, in bytes, of the
363configuration list.
364.It Dv SIOCIFGCLONERS
365Get list of clonable interfaces.
366This request takes an
367.Vt if_clonereq
368structure (see below) as a value-result parameter.
369The
370.Va ifcr_count
371field should be set to the number of
372.Dv IFNAMSIZ
373sized strings that can be fit in the buffer pointed to by
374.Va ifcr_buffer .
375On return,
376.Va ifcr_total
377will be set to the number of clonable interfaces and the buffer pointed
378to by
379.Va ifcr_buffer
380will be filled with the names of clonable interfaces aligned on
381.Dv IFNAMSIZ
382boundaries.
383.El
384.Bd -literal
385/*
386* Structure used in SIOCAIFADDR request.
387*/
388struct ifaliasreq {
389        char    ifra_name[IFNAMSIZ];   /* if name, e.g. "en0" */
390        struct  sockaddr        ifra_addr;
391        struct  sockaddr        ifra_broadaddr;
392        struct  sockaddr        ifra_mask;
393};
394.Ed
395.Bd -literal
396/*
397* Structure used in SIOCGIFCONF request.
398* Used to retrieve interface configuration
399* for machine (useful for programs which
400* must know all networks accessible).
401*/
402struct ifconf {
403    int   ifc_len;		/* size of associated buffer */
404    union {
405        caddr_t    ifcu_buf;
406        struct     ifreq *ifcu_req;
407    } ifc_ifcu;
408#define ifc_buf ifc_ifcu.ifcu_buf /* buffer address */
409#define ifc_req ifc_ifcu.ifcu_req /* array of structures returned */
410};
411.Ed
412.Bd -literal
413/* Structure used in SIOCIFGCLONERS request. */
414struct if_clonereq {
415        int     ifcr_total;     /* total cloners (out) */
416        int     ifcr_count;     /* room for this many in user buffer */
417        char    *ifcr_buffer;   /* buffer for cloner names */
418};
419.Ed
420.Bd -literal
421/* Structure used in SIOCGIFDESCR and SIOCSIFDESCR requests */
422struct ifreq_buffer {
423        size_t  length;         /* length of the buffer */
424        void   *buffer;         /* pointer to userland space buffer */
425};
426.Ed
427.Sh SEE ALSO
428.Xr ioctl 2 ,
429.Xr socket 2 ,
430.Xr intro 4 ,
431.Xr config 8 ,
432.Xr routed 8 ,
433.Xr ifnet 9
434.Sh HISTORY
435The
436.Nm netintro
437manual appeared in
438.Bx 4.3 tahoe .
439