- Introduction
- Configuration
- Running pimd
- Troubleshooting Checklist
- Monitoring
- Large Setups
- Build & Install
- Building from GIT
- Contributing
- Origin & References
pimd is a lightweight, stand-alone PIM-SM/SSM multicast routing daemon available under the free 3-clause BSD license. This is the restored original version from University of Southern California, by Ahmed Helmy, Rusty Eddy and Pavlin Ivanov Radoslavov.
Today pimd is maintained at GitHub. This is the preferred way to download releases, access the GIT sources, report bugs, and send patches or pull requests. Official release tarballs at the homepage and at the GitHub project's release directory.
pimd is developed on Linux and should work as-is out of the box on all major distributions. Other UNIX variants; NetBSD, FreeBSD, and Illumos, may also work, but do not receive the same amount of testing.
pimd ships with a useful pimctl
tool, compatible with all PIM daemons
from the same family: pimd, pimd-dense, pim6sd. It can be a very helpful
little tool when debugging and learning PIM setups. The pimctl API is
documented in the file src/ipc.c
, in case you want to use socat
to
talk to pimd over its UNIX domain socket:
echo "help" |socat - UNIX-CONNECT:/var/run/pimd.sock
For a summary of changes for each release, see the ChangeLog.
The configuration is kept in the file /etc/pimd.conf
, the order of
the statements are in some cases important.
PIM-SM is a designed to be a protocol independent multicast routing protocol. As such it relies on unicast protocols like, e.g, OSPF, RIP, or static routing entries to figure out the reverse path to multicast sources. This information is necessary in setups with more than one route between a multicast sender and a receiver to figure out which PIM router should be the active forwarder.
However, pimd currently cannot retrieve the unicast routing distance (preference) and metric of routes from the system, not from the kernel nor a route manager like zebra. Hence, pimd currently needs to be setup statically on each router using the desired distance and metric for each active interface. If either the distance and/or the metric is missing in an interface configuration, the following two defaults will be used:
default-route-distance <1-255> default: 101
default-route-metric <1-1024> default: 1024
By default pimd starts up on all interfaces it can find, using the above defaults. To configure individual interfaces use:
phyint <address | ifname> ...
You can reference the interface via either its local IPv4 address or its name, e.g., eth0. Some common interface settings are:
-
disable
: Disable pimd on this interface, i.e., do not send or listen for PIM-SM traffic -
dr-priority <1-4294967294>
: The DR Priority option, sent in all all PIM Hello messages. Used instead of the IP address in all DR elections, if all PIM routers in LAN advertise it. The higher, the better, default 1. -
distance <1-255>
: The interface's admin distance value (also confusingly referred to as metric preference in the RFC) in PIM Assert messages. Used withmetric
to elect the active multicast forwarding router. Defaults todefault-route-distance
-
metric <1-1024>
: The cost for traversing this router. Used with thepreference
value above. Defaults todefault-route-metric
More interface settings are available, see the pimd(8) manual page for the full details.
The most notable feature of PIM-SM is that multicast is distributed from
so called Rendezvous Points (RP). Each RP handles distribution of one
or more multicast groups, pimd can be configured to advertise itself as
a candidate RP rp-candidate
, and request to be static RP rp-address
for one or more multicast groups.
rp-address <address> [<group>[/<LENGTH> | masklen <LENGTH]
The rp-address
setting is the same as the Cisco ip pim rp-address
setting to configure static Rendezvous Points. The first argument can
be an IPv4 address or a multicast group address. The default group and
prefix length is 224.0.0.0/16. Static RP's always have priority 1.
rp-candidate [address | ifname] [interval <10-16383>] [priority <0-255>] \
[group-prefix <group>[</LENGTH> | masklen <LENGTH>]]
The Rendezvous Point candidate, or CRP, setting is the same as the Cisco
ip pim rp-candidate
setting. Use it to control which interface that
should be used in RP elections.
-
address | ifname
: Optional local IPv4 address, or interface name to acquire address from. The default is to use the highest active IP address. -
interval <10-16383>
: The CRP advertisement interval, in seconds. Default: 60 seconds -
priority <0-255>
: How important this CRP is compared to others. The lower the value here, the more important the CRP. Like Cisco, pimd defaults to priority 0 when this is left out
In the CRP messages sent out by pimd, one or more multicast groups can be advertised using the following syntax.
group-prefix <group>[</LENGTH> | masklen <LENGTH>]
Each group-prefix
setting defines one multicast group and an optional
mask length, which defaults to 16 if left out. A maximum of 255
multicast group prefix records is possible for the CRP.
To keep track of all Rendezvous Points in a PIM-SM domain there exists a feature called Bootstrap Router. The elected BSR in a PIM-SM domain periodically announces the RP set in Bootstrap messages. For details on PIM BSR operation, see RFC 5059.
bsr-candidate [address | ifname] [priority <0-255>] [interval <10-26214>]
The configuration of a Candidate BootStrap Router (CBSR) is very similar
to that of CRP. If either the address or the interface name is left out
pimd
uses the highest active IP address. If the priority is omitted,
pimd
(like Cisco) defaults to priority 0. If the interval is omitted,
it defaults to the RFC value of 60 seconds.
In a PIM-SM domain there can be two, or more, paths from a designated router (DR) for a multicast sender to reach a receiver. When receivers begin joining multicast groups all data is received via the shared tree (RPT) from each Rendezvous Point (RP). This is often not an optimal route, so when the volume starts exceeding a configurable threshold, on either the last-hop router or the RP itself, the router will attempt to switch to the shortest path tree (SPT) from the multicast source to the receiver.
In versions of pimd prior to 2.2.0 this threshold was confusingly split in two different settings, one for the DR and one for the RP. These settings are still supported, for compatibility reasons and documented in the man-page, but it is strongly recommended to change to the new syntax instead:
spt-threshold [rate <KBPS> | packets <NUM> | infinity] [interval <5-60>]
Only slightly different from the Cisco ip pim spt-threshold
setting,
pimd can trigger a switch to SPT on a rate or number of packets and you
can also tweak the poll interval. It's recommended to keep the interval
in the tens of seconds, the default is 100 sec. The default threshold
is set to zero packets, which will cause a switch over to the SPT after
the first multicast packet is received.
# Interface eth0 is disabled, i.e., pimd will not run there.
phyint eth0 disable
# On this LAN we have a lower numeric IP than other PIM routers
# but we want to take care of forwarding all PIM messages.
phyint eth1 dr-priority 10
# Partake in BSR elections on eth1
bsr-candidate eth1
# Offer to be an RP for all of 224.0.0.0/4
rp-candidate eth1
group-prefix 224.0.0.0 masklen 4
# This is the built-in defaults, switch to SPT on first packet
spt-threshold packets 0 interval 100
Having set up the configuration file, you are ready to run pimd
. As
usual, it is recommended that you start it manually first, to make sure
everything works as expected, before adding it to your system's startup
scripts, with any startup flags it might need.
pimd [-hnrsv] [-f file] [-d subsys1[,...,subsysN]] [-l level]
-n
: Run in foreground, with logs to stdout (for systemd and finit)-s
: Use syslog, default unless-n
-c file
: Utilize the specified configuration file rather than the default,/etc/pimd.conf
-d [subsys1,...,subsysN]
: Subsystems to enable debug for when running the daemon. Optional argument, if left out, all subsystems are enabled. Typepimd -h
for a full list of subsystems-l level
: Log level, one ofnone
,error
,warning
,notice
,info
, ordebug
. Default isnotice
Example:
pimd -f /cfg/pimd.conf
When running multiple instances of pimd, make sure to use the -I ident
argument, otherwise the PID and IPC socket files will be overwritten and
the syslog will also be hard to follow. Note, -I
changes the default
.conf
filename pimd looks for as well, a complete identity change.
Remember to set the correct log level when enabling debug messages,
usually you need -l debug
, and -s
to force messages to syslog
when running in the foreground (-n
).
pimd -d igmp_proto,pim_jp,kernel,pim_register -l debug -n -s
-
Check the TTL of incoming multicast. Remember, the TTL of the multicast stream must be >1 to be routed. Or rather,
>
than thenttl-threshold
of the inboundphyint
-
If you see
Permission denied
in your logs, you are most likely having firewall, or SELinux, problems -
For PIM-SM, make sure you have a Rendezvous-Point (RP) in your network. Check
rp-candidate
(CRP) andbsr-candidate
(CBSR) settings in yourpimd.conf
, orrp-address
if you prefer the static RP approach -
Check the Linux
rp_filter
setting. Many Linux systems have the "strict" setting enabled, "loose" can work but may cause problems in some setups. We recommend disabling it entirely -
PIM is protocol independent so you must have unicast routeing in place already for
pimd
to work. Useping
to verify connectivity between multicast sender and receiver
To see the virtual interface table, including neighboring PIM routers, and the multicast routing table:
pimctl show interfaces
pimctl show neighbor
pimctl show mrt
...
The default command is pimctl show pim
. To watch it continually
(notice the -c
flag to watch(1) to tell it to interpret the ANSI
escape sequences):
watch -cd pimctl
See the pimctl help
usage text for more commands (available only when
a running PIM daemon is available), or the pimctl(8) man page.
Also worth mentioning, pimd
logs important events to the system log,
in particular at startup when it parses the pimd.conf
configuration
file.
pimd is limited to the number of MAXVIFS
interfaces listed in the
kernel headers. In Linux see /usr/include/linux/mroute.h
.
To overcome this limitation, adjust the kernel #define
to, e.g., 1280,
and configure pimd --with-max-vifs=1280
. Please note, this has only
been tested with Linux and will likely not work with other kernels!
With this many interfaces the kernel may run out of memory to let pimd to enable IGMP on all interfaces. In Linux, use sysctl to tweak the following settings:
sysctl -w net.core.optmem_max=327680
sysctl -w net.ipv4.igmp_max_memberships=5120
The configure script and Makefile supports de facto standard settings
and environment variables such as --prefix=PATH
and DESTDIR=
for the
install process. E.g., to install pimd to /usr
instead of the default
/usr/local
, but redirect install to a package directory in /tmp
:
./configure --prefix=/usr --sysconfdir=/etc --localstatedir=/var
make
make DESTDIR=/tmp/pimd-2.3.2-1 install-strip
If you want to contribute, or simply just try out the latest but unreleased features, then you need to know a few things about the GNU build system:
configure.ac
and a per-directoryMakefile.am
are key filesconfigure
andMakefile.in
are generated fromautogen.sh
Makefile
is generated byconfigure
script
To build from GIT you first need to clone the repository and run the
autogen.sh
script. This requires automake
and autoconf
to be
installed on your system.
git clone https://github.com/troglobit/pimd.git
cd pimd/
./autogen.sh
./configure --prefix=/usr --sysconfdir=/etc --localstatedir=/var && make
GIT sources are a moving target and are not recommended for production systems, unless you know what you are doing!
pimd is maintained by Joachim Wiberg at GitHub. If you find bugs, have feature requests, or want to contribute fixes or features, check out the code from GitHub:
git clone https://github.com/troglobit/pimd
cd pimd
See the file CONTRIBUTING.md for further details.
Part of this program has been derived from mrouted. The mrouted program is covered by the 3-clause BSD license in the accompanying file named LICENSE.mrouted.
The mrouted program is COPYRIGHT 2002 by The Board of Trustees of Leland Stanford Junior University.