This program is a bridge between Chaosnet implementations. It supports different link layer implementations:
- Chaos-over-Ethernet (protocol nr 0x0804, cf https://www.iana.org/assignments/ieee-802-numbers/ieee-802-numbers.xhtml)
- Chaos-over-UDP (encapsulation used by e.g. the klh10/its pdp10 emulator, see https://its.victor.se/wiki/ch11)
- Chaos-over-Unix-sockets (used by the usim CADR emulator, see http://www.unlambda.com/cadr/)
- Chaos-over-TLS (see below)
- Chaos-over-IP (using IP protocol 16, cf https://www.iana.org/assignments/protocol-numbers/protocol-numbers.xhtml)
It also implements the transport layer of Chaosnet (using any of the above link layers), see NCP.
- CONTACTS for info about which Chaosnet application protocols are supported - see also NCP (below) for how to add your own.
- CONFIGURATION for how to configure the bridge program.
- EXAMPLES for some example configurations.
- TLS for how to get a certificate for Chaosnet-over-TLS.
- NCP for how to connect a user program to Chaosnet.
- FIREWALL for how to configure the built-in firewall.
- HISTORY for some historic notes.
- COPYRIGHT for copyright notice and acknowledgements.
You can configure the bridge to connect subnets and/or individual hosts.
Use cases could be
- connecting ITSes running on klh10 or simh, or the usim CADR emulator. Rather than configuring your klh10 to handle all other chudp hosts and iptables to forward chudp pkts over the tun interface, keep routing in the bridge program. Adding new chudp hosts now doesn't require klh10 configuration.
- connecting remote Chaosnet-over-Ethernets, e.g. to communicate with others using LambdaDelta (use a Chaos-over-UDP or -over-TLS or -over-IP link between them).
- connecting remote Chaosnet-over-Unix-sockets, e.g. to communicate with others using usim (use a Chaos-over-UDP or -over-TLS or -over-IP link between them).
- connecting remote Chaosnet-over-IP networks, e.g. in case you run TOPS-20 with Chaosnet, or a PDP-10/X.
- and interconnecting these, of course!
There is also support for connecting user programs such as Supdup (in some Unix-like environment) to Chaosnet - read more.
For more info on the Global Chaosnet, see https://chaosnet.net.
Chaosnet packets are encapsulated in UDP packets, using a four-byte header (version=1, function=1, 0, 0), and with a "hardware trailer" (cf Section 2.5 of MIT AI Memo 628) containing the destination and source addresses and an Internet Checksum. Packets are sent in "little-endian" order, i.e. with the least significant byte of a 16-bit word before the most significant byte. (I'm really sorry about this, and might develop version 2 of the protocol with the only change being big-endian byte order.)
When configured to use Chaos-over-UDP ("chudp", see the configuration section)
- the
dynamic
keyword can be used to allow new hosts to be added to the configuration by simply sending a chudp packet to us. This feature is not as useful here as in klh10, since it's easy to configure new links and fast to restart the bridge, as opposed to a whole ITS system. - host names given in chudp links (see configuration) are re-parsed every five minutes or so, to support dynamic DNS entries (hosts changing addresses). (Maybe this should be configurable.)
For tracing traffic, you might want to use tshark (or Wireshark) with the provided dissector script.
Chaosnet packets are sent over a named Unix socket, with a 4-byte header (length MSB, length LSB, 1, 0). Packets are sent in "big-endian" order, with a "hardware trailer".
When configured to use Chaos-over-unix-sockets, you need to also run the "chaosd" server (found with the usim CADR emulator, see http://www.unlambda.com/cadr/, or at https://tumbleweed.nu/lm-3/). There can be only one such server per host system (on the same host as the bridge) since the named socket of the server is constant.
(Note that the modern usim at https://tumbleweed.nu/lm-3/ does not need the "chaosd" server, but can connect directly to cbridge using Chaos-over-UDP.)
Chaosnet packets are sent using the standard Ethernet protocol 0x0804. No "hardware trailer" is used (cf Section 2.5 of MIT AI Memo 628), since the Ethernet header does the corresponding job. Packets are sent in "big-endian" order.
When configured to use Ethernet, ARP for Chaosnet is used:
- ARP packets are sent and received in a standard manner to find ethernet-chaos mappings
- Proxy ARP is used to inform the Ether hosts about non-Ethernet hosts (e.g chudp or unix-socket hosts)
For tracing traffic, you might want to use tshark (or Wireshark) with the provided dissector script.
Chaosnet packets are sent in IP/IPv6 packets, using the standard IP protocol 16. Packets are sent in "big-endian" order, most often (but not always) with a "hardware trailer".
Chaosnet addresses are mapped to IP/IPv6 addresses either individually, or for a whole subnet (see configuration).
Chaosnet addresses where the host byte is 0xFF cannot be used with subnet mappings on IPv4, since they map to the broadcast address. Broadcast on IPv6 (e.g for sending routing packets on a subnet) is Not Yet Implemented.
Requires libpcap-dev
and libnet1-dev
(on Linux) or libpcap
and libnet11
(on Mac, using port
).
For tracing traffic, you might want to use tshark (or Wireshark) with the provided dissector script.
Chaosnet packets are sent over TLS, with a 2-byte header (length MSB, length LSB). Packets are sent in "big-endian" order, with a "hardware trailer".
There are different reasons to want to use TLS:
- one is for improved security (confidentiality, authenticity), and
- another is for clients which don't have externally reachable and stable IP addresses and thus are not reachable by UDP. TCP would suffice, but since clients don't have stable IPs, it would be hard to firewall - instead you need an open server which is not so nice/secure. TLS helps with the authentication.
When configured to use Chaos-over-TLS, it needs some certificate infrastructure. There is one for the Global Chaosnet, see TLS
TLS is asymmetric, in the sense that one end is the server which the clients connect to.
Requires libssl-dev
to compile on Linux; on Mac with port
, install openssl
.
A simple unix sockets interface ("API") for connecting "any old program" to Chaosnet, e.g. Supdup. See the docs and Supdup for Chaosnet. There is also a higher-level Python library.
When configuring your Chaosnets, you should really think about routing and subnets properly. Trying to interconnect two "segments" of the same subnet on different media is harder to get right than interconnecting two different subnets. Attaching single hosts to a subnet through this bridge is more doable.
A bridge between two subnets needs an address on each one of them. In
the configuration, see the myaddr
parameter for
links.
In order to minimise address collisions and routing problems, the subnet 0376 octal, is reserved for private non-routed use, such as experiments. No routing information about that subnet should be sent outside that subnet, no packets from that subnet should be sent to other subnets, and any packets received from that subnet on another subnet should be dropped. This is similar to the IP private networks such as 10.x.y.z or 192.168.x.y.
Additional private non-routed subnets can be defined using the
private
keyword in the configuration, which can
also define a file for hostname-address mappings for private
networks. (Such networks typically do not have DNS entries.)
If the process receives a SIGUSR1 signal, it prints things about its configuration, routing and statistics. If SIGINFO is defined (e.g. on macOS, using ctrl-T in bash), that signal does the same.
Should BRD packets be forwarded towards subnets in the bitmask which we know a route to? This would make it possible to do a "remote broadcast" on a net we're not directly connected to. (Currently they are only forwarded on subnets we are directly connected to, which means they can still reach remote subnets, but only by being broadcast on every net along the way.)
- validate configuration (at least warn about crazy things, subnet-specific address on each link, multiple links/routes to same dest))
- improve logging (avoid mixing output from different threads, improve granularity e.g. to only log "significant" events, "levels" and "facilities" a'la LambdaDelta)
- rewrite BPF part (Chaos-over-Ethernet) using libpcap (for portability and simplicity)
- invent version 2 of CHUDP to send packets in network order, like all the others, and thus avoid swapping/copying data all over (except for version 1 of CHUDP)
- detect unexpected traffic (e.g. traffic from a known subnet coming on a different link)
- make Open Genera use tap instead of tun, to allow Chaosnet (quite different project, but for Chaos interoperability)
When looking for a route, first a route for the individual host is searched for, then the subnet. The bridge sends RUT routing packets about subnets (but not about individual host routes, since that can't be done with RUT).
Separate threads are started to handle input from different link types (several for TLS). Each thread is only started if the configuration needs it (e.g. if you configure an ether link, the ethernet thread is started).
Often the Ethernet link can NOT send and receive to the host system running the bridge program, or other programs using the same mechanism, such as klh10 using Chaos-over-Ether. (With the latest version of LambdaDelta, the bridge program plays nicely though.) If you have problems, run the bridge on another system on your network.