INTRO(4N) INTRO(4N) NAME networking - introduction to networking facilities SYNOPSIS #include #include #include DESCRIPTION This section briefly describes the networking facilities available in the system. Documentation in this part of section 4 is broken up into three areas: _p_r_o_t_o_c_o_l _f_a_m_i_l_i_e_s (domains), _p_r_o_t_o_c_o_l_s, and _n_e_t_w_o_r_k _i_n_t_e_r_‐ _f_a_c_e_s. Entries describing a protocol family are marked ‘‘4F,’’ while entries describing protocol use are marked ‘‘4P.’’ Hardware support for network interfaces are found among the standard ‘‘4’’ entries. All network protocols are associated with a specific _p_r_o_t_o_c_o_l _f_a_m_i_l_y. A protocol family provides basic services to the protocol implementa‐ tion to allow it to function within a specific network environment. These services may include packet fragmentation and reassembly, rout‐ ing, addressing, and basic transport. A protocol family may support multiple methods of addressing, though the current protocol implementa‐ tions do not. A protocol family is normally comprised of a number of protocols, one per _s_o_c_k_e_t(2) type. It is not required that a protocol family support all socket types. A protocol family may contain multi‐ ple protocols supporting the same socket abstraction. A protocol supports one of the socket abstractions detailed in _s_o_c_k_e_t(2). A specific protocol may be accessed either by creating a socket of the appropriate type and protocol family, or by requesting the protocol explicitly when creating a socket. Protocols normally accept only one type of address format, usually determined by the addressing structure inherent in the design of the protocol family/net‐ work architecture. Certain semantics of the basic socket abstractions are protocol specific. All protocols are expected to support the basic model for their particular socket type, but may, in addition, provide non-standard facilities or extensions to a mechanism. For example, a protocol supporting the SOCK_STREAM abstraction may allow more than one byte of out-of-band data to be transmitted per out-of-band message. A network interface is similar to a device interface. Network inter‐ faces comprise the lowest layer of the networking subsystem, interact‐ ing with the actual transport hardware. An interface may support one or more protocol families and/or address formats. The SYNOPSIS section of each network interface entry gives a sample specification of the related drivers for use in providing a system description to the _c_o_n_‐ _f_i_g(8) program. The DIAGNOSTICS section lists messages which may appear on the console and/or in the system error log, _/_u_s_r_/_a_d_m_/_m_e_s_s_a_g_e_s (see _s_y_s_l_o_g_d(8)), due to errors in device operation. PROTOCOLS The system currently supports the DARPA Internet protocols and the Xerox Network Systems(tm) protocols. Raw socket interfaces are pro‐ vided to the IP protocol layer of the DARPA Internet, to the IMP link layer (1822), and to the IDP protocol of Xerox NS. Consult the appro‐ priate manual pages in this section for more information regarding the support for each protocol family. ADDRESSING Associated with each protocol family is an address format. The follow‐ ing address formats are used by the system (and additional formats are defined for possible future implementation): #define AF_UNIX 1 /* local to host (pipes, portals) */ #define AF_INET 2 /* internetwork: UDP, TCP, etc. */ #define AF_IMPLINK 3 /* arpanet imp addresses */ #define AF_PUP 4 /* pup protocols: e.g. BSP */ #define AF_NS 6 /* Xerox NS protocols */ #define AF_HYLINK 15 /* NSC Hyperchannel */ ROUTING The network facilities provided limited packet routing. A simple set of data structures comprise a ‘‘routing table’’ used in selecting the appropriate network interface when transmitting packets. This table contains a single entry for each route to a specific network or host. A user process, the routing daemon, maintains this data base with the aid of two socket-specific _i_o_c_t_l(2) commands, SIOCADDRT and SIOCDELRT. The commands allow the addition and deletion of a single routing table entry, respectively. Routing table manipulations may only be carried out by super-user. A routing table entry has the following form, as defined in <_n_e_t_/_r_o_u_t_e_._h>; struct rtentry { u_long rt_hash; struct sockaddr rt_dst; struct sockaddr rt_gateway; short rt_flags; short rt_refcnt; u_long rt_use; struct ifnet *rt_ifp; }; with _r_t__f_l_a_g_s defined from, #define RTF_UP 0x1 /* route usable */ #define RTF_GATEWAY 0x2 /* destination is a gateway */ #define RTF_HOST 0x4 /* host entry (net otherwise) */ #define RTF_DYNAMIC 0x10 /* created dynamically (by redirect) */ Routing table entries come in three flavors: for a specific host, for all hosts on a specific network, for any destination not matched by entries of the first two types (a wildcard route). When the system is booted and addresses are assigned to the network interfaces, each pro‐ tocol family installs a routing table entry for each interface when it is ready for traffic. Normally the protocol specifies the route through each interface as a ‘‘direct’’ connection to the destination host or network. If the route is direct, the transport layer of a pro‐ tocol family usually requests the packet be sent to the same host spec‐ ified in the packet. Otherwise, the interface is requested to address the packet to the gateway listed in the routing entry (i.e. the packet is forwarded). Routing table entries installed by a user process may not specify the hash, reference count, use, or interface fields; these are filled in by the routing routines. If a route is in use when it is deleted (_r_t__r_e_f_c_n_t is non-zero), the routing entry will be marked down and removed from the routing table, but the resources associated with it will not be reclaimed until all references to it are released. The routing code returns EEXIST if requested to duplicate an existing entry, ESRCH if requested to delete a non-existent entry, or ENOBUFS if insufficient resources were available to install a new route. User processes read the routing tables through the _/_d_e_v_/_k_m_e_m device. The _r_t__u_s_e field contains the number of packets sent along the route. When routing a packet, the kernel will first attempt to find a route to the destination host. Failing that, a search is made for a route to the network of the destination. Finally, any route to a default (‘‘wildcard’’) gateway is chosen. If multiple routes are present in the table, the first route found will be used. If no entry is found, the destination is declared to be unreachable. A wildcard routing entry is specified with a zero destination address value. Wildcard routes are used only when the system fails to find a route to the destination host and network. The combination of wildcard routes and routing redirects can provide an economical mechanism for routing traffic. INTERFACES Each network interface in a system corresponds to a path through which messages may be sent and received. A network interface usually has a hardware device associated with it, though certain interfaces such as the loopback interface, _l_o(4), do not. The following _i_o_c_t_l calls may be used to manipulate network interfaces. The _i_o_c_t_l is made on a socket (typically of type SOCK_DGRAM) in the desired domain. Unless specified otherwise, the request takes an _i_f_r_e_‐ _q_u_e_s_t structure as its parameter. This structure has the form struct ifreq { char ifr_name[16]; /* name of interface (e.g. "ec0") */ union { struct sockaddr ifru_addr; struct sockaddr ifru_dstaddr; struct sockaddr ifru_broadaddr; short ifru_flags; int ifru_metric; } ifr_ifru; #define ifr_addr ifr_ifru.ifru_addr /* address */ #define ifr_dstaddr ifr_ifru.ifru_dstaddr /* other end of p-to-p link */ #define ifr_broadaddr ifr_ifru.ifru_broadaddr /* broadcast address */ #define ifr_flags ifr_ifru.ifru_flags /* flags */ #define ifr_metric ifr_ifru.ifru_metric /* routing metric */ }; SIOCSIFADDR Set interface address for protocol family. Following the address assignment, the ‘‘initialization’’ routine for the interface is called. SIOCGIFADDR Get interface address for protocol family. SIOCSIFDSTADDR Set point to point address for protocol family and interface. SIOCGIFDSTADDR Get point to point address for protocol family and interface. SIOCSIFBRDADDR Set broadcast address for protocol family and interface. SIOCGIFBRDADDR Get broadcast address for protocol family and interface. SIOCSIFFLAGS Set interface flags field. If the interface is marked down, any processes currently routing packets through the interface are notified; some interfaces may be reset so that incoming packets are no longer received. When marked up again, the interface is reinitialized. SIOCGIFFLAGS Get interface flags. SIOCSIFMETRIC Set interface routing metric. The metric is used only by user- level routers. SIOCGIFMETRIC Get interface metric. SIOCGIFCONF Get interface configuration list. This request takes an _i_f_c_o_n_f structure (see below) as a value-result parameter. The _i_f_c__l_e_n field should be initially set to the size of the buffer pointed to by _i_f_c__b_u_f. On return it will contain the length, in bytes, of the configuration list. /* * Structure used in SIOCGIFCONF request. * Used to retrieve interface configuration * for machine (useful for programs which * must know all networks accessible). */ struct ifconf { int ifc_len; /* size of associated buffer */ union { caddr_t ifcu_buf; struct ifreq *ifcu_req; } ifc_ifcu; #define ifc_buf ifc_ifcu.ifcu_buf /* buffer address */ #define ifc_req ifc_ifcu.ifcu_req /* array of structures returned */ }; SEE ALSO socket(2), ioctl(2), intro(4), config(8), routed(8C) 4.2 Berkeley Distribution June 1, 1986 INTRO(4N)