.\" $OpenBSD: mrouted.8,v 1.15 2004/04/03 21:53:15 jmc Exp $ .\" The mrouted program is covered by the license in the accompanying file .\" named "LICENSE". Use of the mrouted program represents acceptance of .\" the terms and conditions listed in that file. .\" .\" The mrouted program is COPYRIGHT 1989 by The Board of Trustees of .\" Leland Stanford Junior University. .Dd May 8, 1995 .Dt MROUTED 8 .Os .Sh NAME .Nm mrouted .Nd IP multicast routing daemon .Sh SYNOPSIS .Nm mrouted .Op Fl c Ar config_file .Op Fl d Ar debug_level .Op Fl p .Sh DESCRIPTION .Nm is an implementation of the Distance-Vector Multicast Routing Protocol (DVMRP), an earlier version of which is specified in RFC 1075. It maintains topological knowledge via a distance-vector routing protocol (like RIP, described in RFC 1058), upon which it implements a multicast datagram forwarding algorithm called Reverse Path Multicasting. .Pp .Nm forwards a multicast datagram along a shortest (reverse) path tree rooted at the subnet on which the datagram originates. The multicast delivery tree may be thought of as a broadcast delivery tree that has been pruned back so that it does not extend beyond those subnetworks that have members of the destination group. Hence, datagrams are not forwarded along those branches which have no listeners of the multicast group. The IP time-to-live of a multicast datagram can be used to limit the range of multicast datagrams. .Pp In order to support multicasting among subnets that are separated by (unicast) routers that do not support IP multicasting, .Nm includes support for "tunnels", which are virtual point-to-point links between pairs of .Nm daemons located anywhere in an internet. IP multicast packets are encapsulated for transmission through tunnels, so that they look like normal unicast datagrams to intervening routers and subnets. The encapsulation is added on entry to a tunnel, and stripped off on exit from a tunnel. By default, the packets are encapsulated using the IP-in-IP protocol (IP protocol number 4). Older versions of .Nm tunnel use IP source routing, which puts a heavy load on some types of routers. This version does not support IP source route tunneling. .Pp The tunneling mechanism allows .Nm to establish a virtual internet, for the purpose of multicasting only, which is independent of the physical internet, and which may span multiple Autonomous Systems. This capability is intended for experimental support of internet multicasting only, pending widespread support for multicast routing by the regular (unicast) routers. .Nm suffers from the well-known scaling problems of any distance-vector routing protocol, and does not (yet) support hierarchical multicast routing. .Pp .Nm handles multicast routing only; there may or may not be unicast routing software running on the same machine as .Nm mrouted . With the use of tunnels, it is not necessary for .Nm to have access to more than one physical subnet in order to perform multicast forwarding. .Sh INVOCATION If no .Fl d option is given, or if the debug level is specified as 0, .Nm detaches from the invoking terminal. Otherwise, it remains attached to the invoking terminal and responsive to signals from that terminal. If .Fl d is given with no argument, the debug level defaults to 2. Regardless of the debug level, .Nm always writes warning and error messages to the system log daemon. Non-zero debug levels have the following effects: .Pp .Bl -hang -compact -offset indent .It 1 All syslog'ed messages are also printed to stderr. .It 2 All level 1 messages plus notifications of "significant" events are printed to stderr. .It 3 All level 2 messages plus notifications of all packet arrivals and departures are printed to stderr. .El .Pp Upon startup, .Nm writes its pid to the file .Pa /var/run/mrouted.pid . .Sh CONFIGURATION .Nm automatically configures itself to forward on all multicast-capable interfaces, i.e., interfaces that have the IFF_MULTICAST flag set (excluding the loopback "interface"), and it finds other .Nm directly reachable via those interfaces. To override the default configuration, or to add tunnel links to other .Nm mrouted , configuration commands may be placed in .Pa /etc/mrouted.conf (or an alternative file, specified by the .Fl c option). There are five types of configuration commands: .Bl -item -offset indent .It .Tn phyint <local-addr> [disable] [metric <m>] .Bl -tag -width flag -compact -offset indent .It [threshold <t>] [rate_limit <b>] .It [boundary (<boundary-name>|<scoped-addr>/<mask-len>)] .It [altnet <network>/<mask-len>] .El .It .Bl -tag -width flag -compact -offset indent .Tn tunnel <local-addr> <remote-addr> [metric <m>] .It [threshold <t>] [rate_limit <b>] .It [boundary (<boundary-name>|<scoped-addr>/<mask-len>)] .El .It .Tn cache_lifetime <ct> .It .Tn pruning <off/on> .It .Tn name <boundary-name> <scoped-addr>/<mask-len> .El .Pp The file format is free-form; whitespace (including newlines) is not significant. The .Ar boundary and .Ar altnet options may be specified as many times as necessary. .Pp The .Nm phyint command can be used to disable multicast routing on the physical interface identified by local IP address .Ar <local-addr> , or to associate a non-default metric or threshold with the specified physical interface. The local IP address .Ar <local-addr> may be replaced by the interface name (e.g., le0). If a phyint is attached to multiple IP subnets, describe each additional subnet with the .Ar altnet keyword. Phyint commands must precede tunnel commands. .Pp The .Nm tunnel command can be used to establish a tunnel link between local IP address .Ar <local-addr> and remote IP address .Ar <remote-addr> , and to associate a non-default metric or threshold with that tunnel. The local IP address .Ar <local-addr> may be replaced by the interface name (e.g., le0). The remote IP address .Ar <remote-addr> may be replaced by a host name, if and only if the host name has a single IP address associated with it. The tunnel must be set up in the mrouted.conf files of both routers before it can be used. '\"For backwards compatibility with older '\".IR mrouted s, '\"the srcrt keyword specifies '\"encapsulation using IP source routing. .Pp The .Nm cache_lifetime is a value that determines the amount of time that a cached multicast route stays in kernel before timing out. The value of this entry should lie between 300 (5 min) and 86400 (1 day). It defaults to 300. .Pp The .Nm pruning option is provided for .Nm to act as a non-pruning router. It is also possible to start .Nm in a non-pruning mode using the .Fl p option on the command line. It is expected that a router would be configured in this manner for test purposes only. The default mode is pruning enabled. .Pp You may assign names to boundaries to make configuration easier with the .Nm name keyword. The .Ar boundary option on .Nm phyint or .Nm tunnel commands can accept either a name or a boundary. .Pp The .Ar metric is the "cost" associated with sending a datagram on the given interface or tunnel; it may be used to influence the choice of routes. The metric defaults to 1. Metrics should be kept as small as possible, because .Nm cannot route along paths with a sum of metrics greater than 31. .Pp The .Ar threshold is the minimum IP time-to-live required for a multicast datagram to be forwarded to the given interface or tunnel. It is used to control the scope of multicast datagrams. (The TTL of forwarded packets is only compared to the threshold, it is not decremented by the threshold. Every multicast router decrements the TTL by 1.) The default threshold is 1. .Pp In general, all .Nm connected to a particular subnet or tunnel should use the same metric and threshold for that subnet or tunnel. .Pp The .Ar rate_limit option allows the network administrator to specify a certain bandwidth in Kbits/second which would be allocated to multicast traffic. It defaults to 500Kbps on tunnels, and 0 (unlimited) on physical interfaces. .Pp The .Ar boundary option allows an interface to be configured as an administrative boundary for the specified scoped address. Packets belonging to this address will not be forwarded on a scoped interface. The boundary option accepts either a name or a boundary spec. .Pp .Nm will not initiate execution if it has fewer than two enabled vifs, where a vif (virtual interface) is either a physical multicast-capable interface or a tunnel. It will log a warning if all of its vifs are tunnels; such an .Nm configuration would be better replaced by more direct tunnels (i.e., eliminate the middle man). .Sh EXAMPLE CONFIGURATION This is an example configuration for a mythical multicast router at a big school. .Bd -unfilled -compact -offset left # # mrouted.conf example # # Name our boundaries to make it easier. name LOCAL 239.255.0.0/16 name EE 239.254.0.0/16 # # le1 is our gateway to compsci, don't forward our # local groups to them. phyint le1 boundary EE # # le2 is our interface on the classroom net, it has four # different length subnets on it. # Note that you can use either an ip address or an # interface name phyint 172.16.12.38 boundary EE altnet 172.16.15.0/26 altnet 172.16.15.128/26 altnet 172.16.48.0/24 # # atm0 is our ATM interface, which doesn't properly # support multicasting. phyint atm0 disable # # This is an internal tunnel to another EE subnet. # Remove the default tunnel rate limit, since this # tunnel is over ethernets. tunnel 192.168.5.4 192.168.55.101 metric 1 threshold 1 rate_limit 0 # # This is our tunnel to the outside world. # Careful with those boundaries, Eugene. tunnel 192.168.5.4 10.11.12.13 metric 1 threshold 32 boundary LOCAL boundary EE .Ed .Sh SIGNALS .Nm responds to the following signals: .Pp .Bl -tag -width TERM -compact .It HUP restarts .Nm mrouted . The configuration file is reread every time this signal is evoked. .It INT terminates execution gracefully (i.e., by sending good-bye messages to all neighboring routers). .It TERM same as INT .It USR1 dumps the internal routing tables to .Pa /var/tmp/mrouted.dump . .It USR2 dumps the internal cache tables to .Pa /var/tmp/mrouted.cache . .It QUIT dumps the internal routing tables to stderr (only if .Nm was invoked with a non-zero debug level). .El .Pp For convenience in sending signals, .Nm writes its pid to .Pa /var/run/mrouted.pid upon startup. .Sh FILES .Bl -tag -width /var/tmp/mrouted.cache -compact .It Pa /etc/mrouted.conf .It Pa /var/run/mrouted.pid .It Pa /var/tmp/mrouted.dump .It Pa /var/tmp/mrouted.cache .El .Sh EXAMPLES The routing tables look like this: .Pp .Bd -unfilled -compact -offset left Virtual Interface Table Vif Local-Address Metric Thresh Flags 0 36.2.0.8 subnet: 36.2 1 1 querier groups: 224.0.2.1 224.0.0.4 pkts in: 3456 pkts out: 2322323 1 36.11.0.1 subnet: 36.11 1 1 querier groups: 224.0.2.1 224.0.1.0 224.0.0.4 pkts in: 345 pkts out: 3456 2 36.2.0.8 tunnel: 36.8.0.77 3 1 peers: 36.8.0.77 (2.2) boundaries: 239.0.1 : 239.1.2 pkts in: 34545433 pkts out: 234342 3 36.2.0.8 tunnel: 36.6.8.23 3 16 Multicast Routing Table (1136 entries) Origin-Subnet From-Gateway Metric Tmr In-Vif Out-Vifs 36.2 1 45 0 1* 2 3* 36.8 36.8.0.77 4 15 2 0* 1* 3* 36.11 1 20 1 0* 2 3* . . . .Ed .Pp In this example, there are four vifs connecting to two subnets and two tunnels. The vif 3 tunnel is not in use (no peer address). The vif 0 and vif 1 subnets have some groups present; tunnels never have any groups. This instance of .Nm is the one responsible for sending periodic group membership queries on the vif 0 and vif 1 subnets, as indicated by the "querier" flags. The list of boundaries indicate the scoped addresses on that interface. A count of the no. of incoming and outgoing packets is also shown at each interface. .Pp Associated with each subnet from which a multicast datagram can originate is the address of the previous hop router (unless the subnet is directly- connected), the metric of the path back to the origin, the amount of time since we last received an update for this subnet, the incoming vif for multicasts from that origin, and a list of outgoing vifs. "*" means that the outgoing vif is connected to a leaf of the broadcast tree rooted at the origin, and a multicast datagram from that origin will be forwarded on that outgoing vif only if there are members of the destination group on that leaf. .Pp .Nm also maintains a copy of the kernel forwarding cache table. Entries are created and deleted by .Nm mrouted . .Pp The cache tables look like this: .Pp .Bd -unfilled -compact -offset left Multicast Routing Cache Table (147 entries) Origin Mcast-group CTmr Age Ptmr IVif Forwvifs 13.2.116/22 224.2.127.255 3m 2m - 0 1 >13.2.116.19 >13.2.116.196 138.96.48/21 224.2.127.255 5m 2m - 0 1 >138.96.48.108 128.9.160/20 224.2.127.255 3m 2m - 0 1 >128.9.160.45 198.106.194/24 224.2.135.190 9m 28s 9m 0P >198.106.194.22 .Ed .Pp Each entry is characterized by the origin subnet number and mask and the destination multicast group. The 'CTmr' field indicates the lifetime of the entry. The entry is deleted from the cache table when the timer decrements to zero. The 'Age' field is the time since this cache entry was originally created. Since cache entries get refreshed if traffic is flowing, routing entries can grow very old. The 'Ptmr' field is simply a dash if no prune was sent upstream, or the amount of time until the upstream prune will time out. The 'Ivif' field indicates the incoming vif for multicast packets from that origin. Each router also maintains a record of the number of prunes received from neighboring routers for a particular source and group. If there are no members of a multicast group on any downward link of the multicast tree for a subnet, a prune message is sent to the upstream router. They are indicated by a "P" after the vif number. The Forwvifs field shows the interfaces along which datagrams belonging to the source-group are forwarded. A "p" indicates that no datagrams are being forwarded along that interface. An unlisted interface is a leaf subnet with no members of the particular group on that subnet. A "b" on an interface indicates that it is a boundary interface, i.e., traffic will not be forwarded on the scoped address on that interface. An additional line with a ">" as the first character is printed for each source on the subnet. Note that there can be many sources in one subnet. .Sh SEE ALSO .Xr map-mbone 8 , .Xr mrinfo 8 , .Xr mtrace 8 .Pp DVMRP is described, along with other multicast routing algorithms, in the paper "Multicast Routing in Internetworks and Extended LANs" by S. Deering, in the Proceedings of the ACM SIGCOMM '88 Conference. .Sh AUTHORS Steve Deering, Ajit Thyagarajan, Bill Fenner