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749 lines
26 KiB
Plaintext
749 lines
26 KiB
Plaintext
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.. _interfaces-main:
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********************
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Supported Interfaces
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********************
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Reticulum supports using many kinds of devices as networking interfaces, and
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allows you to mix and match them in any way you choose. The number of distinct
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network topologies you can create with Reticulum is more or less endless, but
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common to them all is that you will need to define one or more *interfaces*
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for Reticulum to use.
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The following sections describe the interfaces currently available in Reticulum,
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and gives example configurations for the respective interface types.
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For a high-level overview of how networks can be formed over different interface
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types, have a look at the :ref:`Building Networks<networks-main>` chapter of this
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manual.
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.. _interfaces-auto:
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Auto Interface
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==============
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The Auto Interface enables communication with other discoverable Reticulum
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nodes over autoconfigured IPv6 and UDP. It does not need any functional IP
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infrastructure like routers or DHCP servers, but will require at least some
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sort of switching medium between peers (a wired switch, a hub, a WiFi access
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point or similar), and that link-local IPv6 is enabled in your operating
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system, which should be enabled by default in almost all OSes.
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.. code::
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# This example demonstrates a TCP server interface.
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# It will listen for incoming connections on the
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# specified IP address and port number.
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[[Default Interface]]
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type = AutoInterface
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interface_enabled = True
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# You can create multiple isolated Reticulum
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# networks on the same physical LAN by
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# specifying different Group IDs.
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group_id = reticulum
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# You can also select specifically which
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# kernel networking devices to use.
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devices = wlan0,eth1
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# Or let AutoInterface use all suitable
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# devices except for a list of ignored ones.
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ignored_devices = tun0,eth0
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If you are connected to the Internet with IPv6, and your provider will route
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IPv6 multicast, you can potentially configure the Auto Interface to globally
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autodiscover other Reticulum nodes within your selected Group ID. You can specify
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the discovery scope by setting it to one of ``link``, ``admin``, ``site``,
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``organisation`` or ``global``.
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.. code::
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[[Default Interface]]
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type = AutoInterface
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interface_enabled = True
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# Configure global discovery
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group_id = custom_network_name
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discovery_scope = global
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# Other configuration options
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discovery_port = 48555
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data_port = 49555
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.. _interfaces-i2p:
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I2P Interface
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=============
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The I2P interface lets you connect Reticulum instances over the
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`Invisible Internet Protocol <https://i2pd.website>`_. This can be
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especially useful in cases where you want to host a globally reachable
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Reticulum instance, but do not have access to any public IP addresses,
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have a frequently changing IP address, or have firewalls blocking
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inbound traffic.
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Using the I2P interface, you will get a globally reachable, portable
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and persistent I2P address that your Reticulum instance can be reached
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at.
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To use the I2P interface, you must have an I2P router running
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on your system. The easiest way to achieve this is to download and
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install the `latest release <https://github.com/PurpleI2P/i2pd/releases/latest>`_
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of the ``i2pd`` package. For more details about I2P, see the
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`geti2p.net website <https://geti2p.net/en/about/intro>`_.
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When an I2P router is running on your system, you can simply add
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an I2P interface to Reticulum:
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.. code::
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[[I2P]]
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type = I2PInterface
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interface_enabled = yes
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connectable = yes
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On the first start, Reticulum will generate a new I2P address for the
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interface and start listening for inbound traffic on it. This can take
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a while the first time, especially if your I2P router was also just
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started, and is not yet well-connected to the I2P network. When ready,
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you should see I2P base32 address printed to your log file. You can
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also inspect the status of the interface using the ``rnstatus`` utility.
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To connect to other Reticulum instances over I2P, just add a comma-separated
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list of I2P base32 addresses to the ``peers`` option of the interface:
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.. code::
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[[I2P]]
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type = I2PInterface
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interface_enabled = yes
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connectable = yes
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peers = 5urvjicpzi7q3ybztsef4i5ow2aq4soktfj7zedz53s47r54jnqq.b32.i2p
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It can take anywhere from a few seconds to a few minutes to establish
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I2P connections to the desired peers, so Reticulum handles the process
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in the background, and will output relevant events to the log.
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**Please Note!** While the I2P interface is the simplest way to use
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Reticulum over I2P, it is also possible to tunnel the TCP server and
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client interfaces over I2P manually. This can be useful in situations
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where more control is needed, but requires manual tunnel setup through
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the I2P daemon configuration.
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It is important to note that the two methods are *interchangably compatible*.
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You can use the I2PInterface to connect to a TCPServerInterface that
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was manually tunneled over I2P, for example. This offers a high degree
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of flexibility in network setup, while retaining ease of use in simpler
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use-cases.
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.. _interfaces-tcps:
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TCP Server Interface
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====================
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The TCP Server interface is suitable for allowing other peers to connect over
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the Internet or private IP networks. When a TCP server interface has been
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configured, other Reticulum peers can connect to it with a TCP Client interface.
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.. code::
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# This example demonstrates a TCP server interface.
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# It will listen for incoming connections on the
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# specified IP address and port number.
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[[TCP Server Interface]]
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type = TCPServerInterface
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interface_enabled = True
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# This configuration will listen on all IP
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# interfaces on port 4242
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listen_ip = 0.0.0.0
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listen_port = 4242
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# Alternatively you can bind to a specific IP
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# listen_ip = 10.0.0.88
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# listen_port = 4242
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# Or a specific network device
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# device = eth0
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# port = 4242
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**Please Note!** The TCP interfaces support tunneling over I2P, but to do so reliably,
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you must use the i2p_tunneled option:
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.. code::
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[[TCP Server on I2P]]
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type = TCPServerInterface
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interface_enabled = yes
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listen_ip = 127.0.0.1
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listen_port = 5001
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i2p_tunneled = yes
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In almost all cases, it is easier to use the dedicated ``I2PInterface``, but for complete
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control, and using I2P routers running on external systems, this option also exists.
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.. _interfaces-tcpc:
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TCP Client Interface
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====================
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To connect to a TCP server interface, you would naturally use the TCP client
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interface. Many TCP Client interfaces from different peers can connect to the
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same TCP Server interface at the same time.
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The TCP interface types can also tolerate intermittency in the IP link layer.
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This means that Reticulum will gracefully handle IP links that go up and down,
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and restore connectivity after a failure, once the other end of a TCP interface reappears.
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.. code::
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# Here's an example of a TCP Client interface. The
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# target_host can either be an IP address or a hostname.
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[[TCP Client Interface]]
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type = TCPClientInterface
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interface_enabled = True
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target_host = 127.0.0.1
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target_port = 4242
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It is also possible to use this interface type to connect via other programs
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or hardware devices that expose a KISS interface on a TCP port, for example
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software-based soundmodems. To do this, use the ``kiss_framing`` option:
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.. code::
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# Here's an example of a TCP Client interface that connects
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# to a software TNC soundmodem on a KISS over TCP port.
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[[TCP KISS Interface]]
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type = TCPClientInterface
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interface_enabled = True
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kiss_framing = True
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target_host = 127.0.0.1
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target_port = 8001
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**Caution!** Only use the KISS framing option when connecting to external devices
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and programs like soundmodems and similar over TCP. When using the
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``TCPClientInterface`` in conjunction with the ``TCPServerInterface`` you should
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never enable ``kiss_framing``, since this will disable internal reliability and
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recovery mechanisms that greatly improves performance over unreliable and
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intermittent TCP links.
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**Please Note!** The TCP interfaces support tunneling over I2P, but to do so reliably,
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you must use the i2p_tunneled option:
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.. code::
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[[TCP Client over I2P]]
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type = TCPClientInterface
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interface_enabled = yes
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target_host = 127.0.0.1
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target_port = 5001
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i2p_tunneled = yes
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.. _interfaces-udp:
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UDP Interface
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=============
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A UDP interface can be useful for communicating over IP networks, both
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private and the internet. It can also allow broadcast communication
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over IP networks, so it can provide an easy way to enable connectivity
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with all other peers on a local area network.
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*Please Note!* Using broadcast UDP traffic has performance implications,
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especially on WiFi. If your goal is simply to enable easy communication
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with all peers in your local Ethernet broadcast domain, the
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:ref:`Auto Interface<interfaces-auto>` performs better, and is even
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easier to use.
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.. code::
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# This example enables communication with other
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# local Reticulum peers over UDP.
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[[UDP Interface]]
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type = UDPInterface
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interface_enabled = True
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listen_ip = 0.0.0.0
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listen_port = 4242
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forward_ip = 255.255.255.255
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forward_port = 4242
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# The above configuration will allow communication
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# within the local broadcast domains of all local
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# IP interfaces.
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# Instead of specifying listen_ip, listen_port,
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# forward_ip and forward_port, you can also bind
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# to a specific network device like below.
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# device = eth0
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# port = 4242
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# Assuming the eth0 device has the address
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# 10.55.0.72/24, the above configuration would
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# be equivalent to the following manual setup.
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# Note that we are both listening and forwarding to
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# the broadcast address of the network segments.
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# listen_ip = 10.55.0.255
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# listen_port = 4242
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# forward_ip = 10.55.0.255
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# forward_port = 4242
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# You can of course also communicate only with
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# a single IP address
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# listen_ip = 10.55.0.15
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# listen_port = 4242
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# forward_ip = 10.55.0.16
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# forward_port = 4242
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.. _interfaces-rnode:
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RNode LoRa Interface
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====================
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To use Reticulum over LoRa, the `RNode <https://unsigned.io/rnode/>`_ interface
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can be used, and offers full control over LoRa parameters.
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.. code::
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# Here's an example of how to add a LoRa interface
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# using the RNode LoRa transceiver.
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[[RNode LoRa Interface]]
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type = RNodeInterface
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# Enable interface if you want use it!
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interface_enabled = True
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# Serial port for the device
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port = /dev/ttyUSB0
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# Set frequency to 867.2 MHz
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frequency = 867200000
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# Set LoRa bandwidth to 125 KHz
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bandwidth = 125000
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# Set TX power to 7 dBm (5 mW)
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txpower = 7
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# Select spreading factor 8. Valid
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# range is 7 through 12, with 7
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# being the fastest and 12 having
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# the longest range.
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spreadingfactor = 8
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# Select coding rate 5. Valid range
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# is 5 throough 8, with 5 being the
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# fastest, and 8 the longest range.
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codingrate = 5
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# You can configure the RNode to send
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# out identification on the channel with
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# a set interval by configuring the
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# following two parameters.
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# id_callsign = MYCALL-0
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# id_interval = 600
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# For certain homebrew RNode interfaces
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# with low amounts of RAM, using packet
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# flow control can be useful. By default
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# it is disabled.
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flow_control = False
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.. _interfaces-serial:
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Serial Interface
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================
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||
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Reticulum can be used over serial ports directly, or over any device with a
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serial port, that will transparently pass data. Useful for communicating
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directly over a wire-pair, or for using devices such as data radios and lasers.
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||
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.. code::
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[[Serial Interface]]
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type = SerialInterface
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interface_enabled = True
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# Serial port for the device
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port = /dev/ttyUSB0
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# Set the serial baud-rate and other
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# configuration parameters.
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speed = 115200
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databits = 8
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parity = none
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stopbits = 1
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||
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.. _interfaces-pipe:
|
||
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||
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Pipe Interface
|
||
|
==============
|
||
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||
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Using this interface, Reticulum can use any program as an interface via `stdin` and
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`stdout`. This can be used to easily create virtual interfaces, or to interface with
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||
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custom hardware or other systems.
|
||
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||
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.. code::
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||
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||
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[[Pipe Interface]]
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||
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type = PipeInterface
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interface_enabled = True
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||
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# External command to execute
|
||
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command = netcat -l 5757
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||
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# Optional respawn delay, in seconds
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||
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respawn_delay = 5
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||
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||
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Reticulum will write all packets to `stdin` of the ``command`` option, and will
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continuously read and scan its `stdout` for Reticulum packets. If ``EOF`` is reached,
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||
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Reticulum will try to respawn the program after waiting for ``respawn_interval`` seconds.
|
||
|
|
||
|
.. _interfaces-kiss:
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||
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|
||
|
KISS Interface
|
||
|
==============
|
||
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||
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With the KISS interface, you can use Reticulum over a variety of packet
|
||
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radio modems and TNCs, including `OpenModem <https://unsigned.io/openmodem/>`_.
|
||
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KISS interfaces can also be configured to periodically send out beacons
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||
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for station identification purposes.
|
||
|
|
||
|
.. code::
|
||
|
|
||
|
[[Packet Radio KISS Interface]]
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||
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type = KISSInterface
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||
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interface_enabled = True
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||
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||
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# Serial port for the device
|
||
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port = /dev/ttyUSB1
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||
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||
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# Set the serial baud-rate and other
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||
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# configuration parameters.
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||
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speed = 115200
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databits = 8
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parity = none
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||
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stopbits = 1
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||
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||
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# Set the modem preamble.
|
||
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preamble = 150
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||
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||
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# Set the modem TX tail.
|
||
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txtail = 10
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||
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||
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# Configure CDMA parameters. These
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||
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# settings are reasonable defaults.
|
||
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persistence = 200
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||
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slottime = 20
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||
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|
||
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# You can configure the interface to send
|
||
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# out identification on the channel with
|
||
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# a set interval by configuring the
|
||
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# following two parameters. The KISS
|
||
|
# interface will only ID if the set
|
||
|
# interval has elapsed since it's last
|
||
|
# actual transmission. The interval is
|
||
|
# configured in seconds.
|
||
|
# This option is commented out and not
|
||
|
# used by default.
|
||
|
# id_callsign = MYCALL-0
|
||
|
# id_interval = 600
|
||
|
|
||
|
# Whether to use KISS flow-control.
|
||
|
# This is useful for modems that have
|
||
|
# a small internal packet buffer, but
|
||
|
# support packet flow control instead.
|
||
|
flow_control = false
|
||
|
|
||
|
.. _interfaces-ax25:
|
||
|
|
||
|
AX.25 KISS Interface
|
||
|
====================
|
||
|
|
||
|
If you're using Reticulum on amateur radio spectrum, you might want to
|
||
|
use the AX.25 KISS interface. This way, Reticulum will automatically
|
||
|
encapsulate it's traffic in AX.25 and also identify your stations
|
||
|
transmissions with your callsign and SSID.
|
||
|
|
||
|
Only do this if you really need to! Reticulum doesn't need the AX.25
|
||
|
layer for anything, and it incurs extra overhead on every packet to
|
||
|
encapsulate in AX.25.
|
||
|
|
||
|
A more efficient way is to use the plain KISS interface with the
|
||
|
beaconing functionality described above.
|
||
|
|
||
|
.. code::
|
||
|
|
||
|
[[Packet Radio AX.25 KISS Interface]]
|
||
|
type = AX25KISSInterface
|
||
|
|
||
|
# Set the station callsign and SSID
|
||
|
callsign = NO1CLL
|
||
|
ssid = 0
|
||
|
|
||
|
# Enable interface if you want use it!
|
||
|
interface_enabled = True
|
||
|
|
||
|
# Serial port for the device
|
||
|
port = /dev/ttyUSB2
|
||
|
|
||
|
# Set the serial baud-rate and other
|
||
|
# configuration parameters.
|
||
|
speed = 115200
|
||
|
databits = 8
|
||
|
parity = none
|
||
|
stopbits = 1
|
||
|
|
||
|
# Set the modem preamble. A 150ms
|
||
|
# preamble should be a reasonable
|
||
|
# default, but may need to be
|
||
|
# increased for radios with slow-
|
||
|
# opening squelch and long TX/RX
|
||
|
# turnaround
|
||
|
preamble = 150
|
||
|
|
||
|
# Set the modem TX tail. In most
|
||
|
# cases this should be kept as low
|
||
|
# as possible to not waste airtime.
|
||
|
txtail = 10
|
||
|
|
||
|
# Configure CDMA parameters. These
|
||
|
# settings are reasonable defaults.
|
||
|
persistence = 200
|
||
|
slottime = 20
|
||
|
|
||
|
# Whether to use KISS flow-control.
|
||
|
# This is useful for modems with a
|
||
|
# small internal packet buffer.
|
||
|
flow_control = false
|
||
|
|
||
|
.. _interfaces-options:
|
||
|
|
||
|
Common Interface Options
|
||
|
========================
|
||
|
|
||
|
A number of general configuration options are available on most interfaces.
|
||
|
These can be used to control various aspects of interface behaviour.
|
||
|
|
||
|
|
||
|
* | The ``enabled`` option tells Reticulum whether or not
|
||
|
to bring up the interface. Defaults to ``False``. For any
|
||
|
interface to be brought up, the ``enabled`` option
|
||
|
must be set to ``True`` or ``Yes``.
|
||
|
|
||
|
* | The ``mode`` option allows selecting the high-level behaviour
|
||
|
of the interface from a number of options.
|
||
|
|
||
|
- The default value is ``full``. In this mode, all discovery,
|
||
|
meshing and transport functionality is available.
|
||
|
|
||
|
- In the ``access_point`` (or shorthand ``ap``) mode, the
|
||
|
interface will operate as a network access point. In this
|
||
|
mode, announces will not be automatically broadcasted on
|
||
|
the interface, and paths to destinations on the interface
|
||
|
will have a much shorter expiry time. This mode is useful
|
||
|
for creating interfaces that are mostly quiet, unless when
|
||
|
someone is actually using them. An example of this could
|
||
|
be a radio interface serving a wide area, where users are
|
||
|
expected to connect momentarily, use the network, and then
|
||
|
disappear again.
|
||
|
|
||
|
* | The ``outgoing`` option sets whether an interface is allowed
|
||
|
to transmit. Defaults to ``True``. If set to ``False`` or ``No``
|
||
|
the interface will only receive data, and never transmit.
|
||
|
|
||
|
* | The ``network_name`` option sets the virtual network name for
|
||
|
the interface. This allows multiple separate network segments
|
||
|
to exist on the same physical channel or medium.
|
||
|
|
||
|
* | The ``passphrase`` option sets an authentication passphrase on
|
||
|
the interface. This option can be used in conjunction with the
|
||
|
``network_name`` option, or be used alone.
|
||
|
|
||
|
* | The ``ifac_size`` option allows customising the length of the
|
||
|
Interface Authentication Codes carried by each packet on named
|
||
|
and/or authenticated network segments. It is set by default to
|
||
|
a size suitable for the interface in question, but can be set
|
||
|
to a custom size between 8 and 512 bits by using this option.
|
||
|
In normal usage, this option should not be changed from the
|
||
|
default.
|
||
|
|
||
|
* | The ``announce_cap`` option lets you configure the maximum
|
||
|
bandwidth to allocate, at any given time, to propagating
|
||
|
announces and other network upkeep traffic. It is configured at
|
||
|
2% by default, and should normally not need to be changed. Can
|
||
|
be set to any value between ``1`` and ``100``.
|
||
|
|
||
|
*If an interface exceeds its announce cap, it will queue announces
|
||
|
for later transmission. Reticulum will always prioritise propagating
|
||
|
announces from nearby nodes first. This ensures that the local
|
||
|
topology is prioritised, and that slow networks are not overwhelmed
|
||
|
by interconnected fast networks.*
|
||
|
|
||
|
*Destinations that are rapidly re-announcing will be down-prioritised
|
||
|
further. Trying to get "first-in-line" by announce spamming will have
|
||
|
the exact opposite effect: Getting moved to the back of the queue every
|
||
|
time a new announce from the excessively announcing destination is received.*
|
||
|
|
||
|
*This means that it is always beneficial to select a balanced
|
||
|
announce rate, and not announce more often than is actually necesarry
|
||
|
for your application to function.*
|
||
|
|
||
|
* | The ``bitrate`` option configures the interface bitrate.
|
||
|
Reticulum will use interface speeds reported by hardware, or
|
||
|
try to guess a suitable rate when the hardware doesn't report
|
||
|
any. In most cases, the automatically found rate should be
|
||
|
sufficient, but it can be configured by using the ``bitrate``
|
||
|
option, to set the interface speed in *bits per second*.
|
||
|
|
||
|
|
||
|
.. _interfaces-modes:
|
||
|
|
||
|
Interface Modes
|
||
|
===============
|
||
|
|
||
|
The optional ``mode`` setting is available on all interfaces, and allows
|
||
|
selecting the high-level behaviour of the interface from a number of modes.
|
||
|
These modes affect how Reticulum selects paths in the network, how announces
|
||
|
are propagated, how long paths are valid and how paths are discovered.
|
||
|
|
||
|
Configuring modes on interfaces is **not** strictly necessary, but can be useful
|
||
|
when building or connecting to more complex networks. If your Reticulum
|
||
|
instance is not running a Transport Node, it is rarely useful to configure
|
||
|
interface modes, and in such cases interfaces should generally be left in
|
||
|
the default mode.
|
||
|
|
||
|
* | The default mode is ``full``. In this mode, all discovery,
|
||
|
meshing and transport functionality is activated.
|
||
|
|
||
|
* | The ``gateway`` mode (or shorthand ``gw``) also has all
|
||
|
discovery, meshing and transport functionality available,
|
||
|
but will additionally try to discover unknown paths on
|
||
|
behalf of other nodes residing on the ``gateway`` interface.
|
||
|
If Reticulum receives a path request for an unknown
|
||
|
destination, from a node on a ``gateway`` interface, it
|
||
|
will try to discover this path via all other active interfaces,
|
||
|
and forward the discovered path to the requestor if one is
|
||
|
found.
|
||
|
|
||
|
| If you want to allow other nodes to widely resolve paths or connect
|
||
|
to a network via an interface, it might be useful to put it in this
|
||
|
mode. By creating a chain of ``gateway`` interfaces, other
|
||
|
nodes will be able to immediately discover paths to any
|
||
|
destination along the chain.
|
||
|
|
||
|
| *Please note!* It is the interface *facing the clients* that
|
||
|
must be put into ``gateway`` mode for this to work, not
|
||
|
the interface facing the wider network (for this, the ``boundary``
|
||
|
mode can be useful, though).
|
||
|
|
||
|
* | In the ``access_point`` (or shorthand ``ap``) mode, the
|
||
|
interface will operate as a network access point. In this
|
||
|
mode, announces will not be automatically broadcasted on
|
||
|
the interface, and paths to destinations on the interface
|
||
|
will have a much shorter expiry time. In addition, path
|
||
|
requests from clients on the access point interface will
|
||
|
be handled in the same way as the ``gateway`` interface.
|
||
|
|
||
|
| This mode is useful for creating interfaces that remain
|
||
|
quiet, until someone actually starts using them. An example
|
||
|
of this could be a radio interface serving a wide area,
|
||
|
where users are expected to connect momentarily, use the
|
||
|
network, and then disappear again.
|
||
|
|
||
|
* | The ``roaming`` mode should be used on interfaces that are
|
||
|
roaming (physically mobile), seen from the perspective of
|
||
|
other nodes in the network. As an example, if a vehicle is
|
||
|
equipped with an external LoRa interface, and an internal,
|
||
|
WiFi-based interface, that serves devices that are moving
|
||
|
*with* the vehicle, the external LoRa interface should be
|
||
|
configured as ``roaming``, and the internal interface can
|
||
|
be left in the default mode. With transport enabled, such
|
||
|
a setup will allow all internal devices to reach each other,
|
||
|
and all other devices that are available on the LoRa side
|
||
|
of the network, when they are in range. Devices on the LoRa
|
||
|
side of the network will also be able to reach devices
|
||
|
internal to the vehicle, when it is in range. Paths via
|
||
|
``roaming`` interfaces also expire faster.
|
||
|
|
||
|
* | The purpose of the ``boundary`` mode is to specify interfaces
|
||
|
that establish connectivity with network segments that are
|
||
|
significantly different than the one this node exists on.
|
||
|
As an example, if a Reticulum instance is part of a LoRa-based
|
||
|
network, but also has a high-speed connection to a
|
||
|
public Transport Node available on the Internet, the interface
|
||
|
connecting over the Internet should be set to ``boundary`` mode.
|
||
|
|
||
|
For a table describing the impact of all modes on announce propagation,
|
||
|
please see the :ref:`Announce Propagation Rules<understanding-announcepropagation>` section.
|
||
|
|
||
|
.. _interfaces-announcerates:
|
||
|
|
||
|
Announce Rate Control
|
||
|
=====================
|
||
|
|
||
|
The built-in announce control mechanisms and the default ``announce_cap``
|
||
|
option described above are sufficient most of the time, but in some cases, especially on fast
|
||
|
interfaces, it may be useful to control the target announce rate. Using the
|
||
|
``announce_rate_target``, ``announce_rate_grace`` and ``announce_rate_penalty``
|
||
|
options, this can be done on a per-interface basis, and moderates the *rate at
|
||
|
which received announces are re-broadcasted to other interfaces*.
|
||
|
|
||
|
* | The ``announce_rate_target`` option sets the minimum amount of time,
|
||
|
in seconds, that should pass between received announces, for any one
|
||
|
destination. As an example, setting this value to ``3600`` means that
|
||
|
announces *received* on this interface will only be re-transmitted and
|
||
|
propagated to other interfaces once every hour, no matter how often they
|
||
|
are received.
|
||
|
|
||
|
* | The optional ``announce_rate_grace`` defines the number of times a destination
|
||
|
can violate the announce rate before the target rate is enforced.
|
||
|
|
||
|
* | The optional ``announce_rate_penalty`` configures an extra amount of
|
||
|
time that is added to the normal rate target. As an example, if a penalty
|
||
|
of ``7200`` seconds is defined, once the rate target is enforced, the
|
||
|
destination in question will only have its announces propagated every
|
||
|
3 hours, until it lowers its actual announce rate to within the target.
|
||
|
|
||
|
These mechanisms, in conjunction with the ``annouce_cap`` mechanisms mentioned
|
||
|
above means that it is essential to select a balanced announce strategy for
|
||
|
your destinations. The more balanced you can make this decision, the easier
|
||
|
it will be for your destinations to make it into slower networks that many hops
|
||
|
away. Or you can prioritise only reaching high-capacity networks with more frequent
|
||
|
announces.
|
||
|
|
||
|
Current statistics and information about announce rates can be viewed using the
|
||
|
``rnpath -r`` command.
|
||
|
|
||
|
It is important to note that there is no one right or wrong way to set up announce
|
||
|
rates. Slower networks will naturally tend towards using less frequent announces to
|
||
|
conserve bandwidth, while very fast networks can support applications that
|
||
|
need very frequent announces. Reticulum implements these mechanisms to ensure
|
||
|
that a large span of network types can seamlessly *co-exist* and interconnect.
|
||
|
|