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910 lines
48 KiB
ReStructuredText
.. _understanding-main:
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***********************
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Understanding Reticulum
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***********************
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This chapter will briefly describe the overall purpose and operating principles of Reticulum.
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It should give you an overview of how the stack works, and an understanding of how to
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develop networked applications using Reticulum.
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This chapter is not an exhaustive source of information on Reticulum, at least not yet. Currently,
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the only complete repository, and final authority on how Reticulum actually functions, is the Python
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reference implementation and API reference. That being said, this chapter is an essential resource in
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understanding how Reticulum works from a high-level perspective, along with the general principles of
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Reticulum, and how to apply them when creating your own networks or software.
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After reading this document, you should be well-equipped to understand how a Reticulum network
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operates, what it can achieve, and how you can use it yourself. If you want to help out with the
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development, this is also the place to start, since it will provide a pretty clear overview of the
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sentiments and the philosophy behind Reticulum, what problems it seeks to solve, and how it
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approaches those solutions.
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.. _understanding-motivation:
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Motivation
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==========
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The primary motivation for designing and implementing Reticulum has been the current lack of
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reliable, functional and secure minimal-infrastructure modes of digital communication. It is my
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belief that it is highly desirable to create a reliable and efficient way to set up long-range digital
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communication networks that can securely allow exchange of information between people and
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machines, with no central point of authority, control, censorship or barrier to entry.
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Almost all of the various networking systems in use today share a common limitation: They
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require large amounts of coordination and centralised trust and power to function. To join such networks, you need approval
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of gatekeepers in control. This need for coordination and trust inevitably leads to an environment of
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central control, where it's very easy for infrastructure operators or governments to control or alter
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traffic, and censor or persecute unwanted actors. It also makes it completely impossible to freely deploy
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and use networks at will, like one would use other common tools that enhance individual agency and freedom.
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Reticulum aims to require as little coordination and trust as possible. It aims to make secure,
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anonymous and permissionless networking and information exchange a tool that anyone can just pick up and use.
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Since Reticulum is completely medium agnostic, it can be used to build networks on whatever is best
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suited to the situation, or whatever you have available. In some cases, this might be packet radio
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links over VHF frequencies, in other cases it might be a 2.4 GHz
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network using off-the-shelf radios, or it might be using common LoRa development boards.
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At the time of release of this document, the fastest and easiest setup for development and testing is using
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LoRa radio modules with an open source firmware (see the section :ref:`Reference Setup<understanding-referencesystem>`),
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connected to any kind of computer or mobile device that Reticulum can run on.
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The ultimate aim of Reticulum is to allow anyone to be their own network operator, and to make it
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cheap and easy to cover vast areas with a myriad of independent, interconnectable and autonomous networks.
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Reticulum **is not** *one network*, it **is a tool** to build *thousands of networks*. Networks without
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kill-switches, surveillance, censorship and control. Networks that can freely interoperate, associate and disassociate
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with each other, and require no central oversight. Networks for human beings. *Networks for the people*.
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.. _understanding-goals:
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Goals
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=====
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To be as widely usable and efficient to deploy as possible, the following goals have been used to
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guide the design of Reticulum:
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* **Fully useable as open source software stack**
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Reticulum must be implemented with, and be able to run using only open source software. This is
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critical to ensuring the availability, security and transparency of the system.
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* **Hardware layer agnosticism**
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Reticulum must be fully hardware agnostic, and shall be useable over a wide range of
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physical networking layers, such as data radios, serial lines, modems, handheld transceivers,
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wired Ethernet, WiFi, or anything else that can carry a digital data stream. Hardware made for
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dedicated Reticulum use shall be as cheap as possible and use off-the-shelf components, so
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it can be easily modified and replicated by anyone interested in doing so.
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* **Very low bandwidth requirements**
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Reticulum should be able to function reliably over links with a transmission capacity as low
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as *5 bits per second*.
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* **Encryption by default**
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Reticulum must use strong encryption by default for all communication.
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* **Initiator Anonymity**
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It must be possible to communicate over a Reticulum network without revealing any identifying
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information about oneself.
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* **Unlicensed use**
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Reticulum shall be functional over physical communication mediums that do not require any
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form of license to use. Reticulum must be designed in a way, so it is usable over ISM radio
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frequency bands, and can provide functional long distance links in such conditions, for example
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by connecting a modem to a PMR or CB radio, or by using LoRa or WiFi modules.
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* **Supplied software**
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In addition to the core networking stack and API, that allows a developer to build
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applications with Reticulum, a basic set of Reticulum-based communication tools must be
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implemented and released along with Reticulum itself. These shall serve both as a
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functional, basic communication suite, and as an example and learning resource to others wishing
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to build applications with Reticulum.
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* **Ease of use**
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The reference implementation of Reticulum is written in Python, to make it easy to use
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and understand. A programmer with only basic experience should be able to use
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Reticulum to write networked applications.
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* **Low cost**
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It shall be as cheap as possible to deploy a communication system based on Reticulum. This
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should be achieved by using cheap off-the-shelf hardware that potential users might already
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own. The cost of setting up a functioning node should be less than $100 even if all parts
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needs to be purchased.
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.. _understanding-basicfunctionality:
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Introduction & Basic Functionality
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==================================
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Reticulum is a networking stack suited for high-latency, low-bandwidth links. Reticulum is at its
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core a *message oriented* system. It is suited for both local point-to-point or point-to-multipoint
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scenarios where all nodes are within range of each other, as well as scenarios where packets need
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to be transported over multiple hops in a complex network to reach the recipient.
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Reticulum does away with the idea of addresses and ports known from IP, TCP and UDP. Instead
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Reticulum uses the singular concept of *destinations*. Any application using Reticulum as its
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networking stack will need to create one or more destinations to receive data, and know the
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destinations it needs to send data to.
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All destinations in Reticulum are _represented_ as a 16 byte hash. This hash is derived from truncating a full
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SHA-256 hash of identifying characteristics of the destination. To users, the destination addresses
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will be displayed as 16 hexadecimal bytes, like this example: ``<13425ec15b621c1d928589718000d814>``.
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The truncation size of 16 bytes (128 bits) for destinations has been chosen as a reasonable trade-off
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between address space
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and packet overhead. The address space accommodated by this size can support many billions of
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simultaneously active devices on the same network, while keeping packet overhead low, which is
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essential on low-bandwidth networks. In the very unlikely case that this address space nears
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congestion, a one-line code change can upgrade the Reticulum address space all the way up to 256
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bits, ensuring the Reticulum address space could potentially support galactic-scale networks.
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This is obviously complete and ridiculous over-allocation, and as such, the current 128 bits should
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be sufficient, even far into the future.
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By default Reticulum encrypts all data using elliptic curve cryptography and AES. Any packet sent to a
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destination is encrypted with a per-packet derived key. Reticulum can also set up an encrypted
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channel to a destination, called a *Link*. Both data sent over Links and single packets offer
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*Initiator Anonymity*. Links additionally offer *Forward Secrecy* by default, employing an Elliptic Curve
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Diffie Hellman key exchange on Curve25519 to derive per-link ephemeral keys. Asymmetric, link-less
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packet communication can also provide forward secrecy, with automatic key ratcheting, by enabling
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ratchets on a per-destination basis. The multi-hop transport, coordination, verification and reliability
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layers are fully autonomous and also based on elliptic curve cryptography.
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Reticulum also offers symmetric key encryption for group-oriented communications, as well as
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unencrypted packets for local broadcast purposes.
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Reticulum can connect to a variety of interfaces such as radio modems, data radios and serial ports,
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and offers the possibility to easily tunnel Reticulum traffic over IP links such as the Internet or
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private IP networks.
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.. _understanding-destinations:
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Destinations
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------------
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To receive and send data with the Reticulum stack, an application needs to create one or more
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destinations. Reticulum uses three different basic destination types, and one special:
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* **Single**
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The *single* destination type is the most common type in Reticulum, and should be used for
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most purposes. It is always identified by a unique public key. Any data sent to this
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destination will be encrypted using ephemeral keys derived from an ECDH key exchange, and will
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only be readable by the creator of the destination, who holds the corresponding private key.
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* **Plain**
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A *plain* destination type is unencrypted, and suited for traffic that should be broadcast to a
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number of users, or should be readable by anyone. Traffic to a *plain* destination is not encrypted.
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Generally, *plain* destinations can be used for broadcast information intended to be public.
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Plain destinations are only reachable directly, and packets addressed to plain destinations are
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never transported over multiple hops in the network. To be transportable over multiple hops in Reticulum, information
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*must* be encrypted, since Reticulum uses the per-packet encryption to verify routing paths and
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keep them alive.
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* **Group**
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The *group* special destination type, that defines a symmetrically encrypted virtual destination.
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Data sent to this destination will be encrypted with a symmetric key, and will be readable by
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anyone in possession of the key, but as with the *plain* destination type, packets to this type
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of destination are not currently transported over multiple hops, although a planned upgrade
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to Reticulum will allow globally reachable *group* destinations.
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* **Link**
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A *link* is a special destination type, that serves as an abstract channel to a *single*
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destination, directly connected or over multiple hops. The *link* also offers reliability and
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more efficient encryption, forward secrecy, initiator anonymity, and as such can be useful even
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when a node is directly reachable. It also offers a more capable API and allows easily carrying
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out requests and responses, large data transfers and more.
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.. _understanding-destinationnaming:
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Destination Naming
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^^^^^^^^^^^^^^^^^^
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Destinations are created and named in an easy to understand dotted notation of *aspects*, and
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represented on the network as a hash of this value. The hash is a SHA-256 truncated to 128 bits. The
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top level aspect should always be a unique identifier for the application using the destination.
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The next levels of aspects can be defined in any way by the creator of the application.
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Aspects can be as long and as plentiful as required, and a resulting long destination name will not
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impact efficiency, as names are always represented as truncated SHA-256 hashes on the network.
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As an example, a destination for a environmental monitoring application could be made up of the
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application name, a device type and measurement type, like this:
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.. code-block:: text
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app name : environmentlogger
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aspects : remotesensor, temperature
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full name : environmentlogger.remotesensor.temperature
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hash : 4faf1b2e0a077e6a9d92fa051f256038
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For the *single* destination, Reticulum will automatically append the associated public key as a
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destination aspect before hashing. This is done to ensure only the correct destination is reached,
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since anyone can listen to any destination name. Appending the public key ensures that a given
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packet is only directed at the destination that holds the corresponding private key to decrypt the
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packet.
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**Take note!** There is a very important concept to understand here:
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* Anyone can use the destination name ``environmentlogger.remotesensor.temperature``
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* Each destination that does so will still have a unique destination hash, and thus be uniquely
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addressable, because their public keys will differ.
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In actual use of *single* destination naming, it is advisable not to use any uniquely identifying
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features in aspect naming. Aspect names should be general terms describing what kind of destination
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is represented. The uniquely identifying aspect is always achieved by appending the public key,
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which expands the destination into a uniquely identifiable one. Reticulum does this automatically.
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Any destination on a Reticulum network can be addressed and reached simply by knowing its
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destination hash (and public key, but if the public key is not known, it can be requested from the
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network simply by knowing the destination hash). The use of app names and aspects makes it easy to
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structure Reticulum programs and makes it possible to filter what information and data your program
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receives.
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To recap, the different destination types should be used in the following situations:
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* **Single**
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When private communication between two endpoints is needed. Supports multiple hops.
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* **Group**
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When private communication between two or more endpoints is needed. Supports multiple hops
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indirectly, but must first be established through a *single* destination.
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* **Plain**
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When plain-text communication is desirable, for example when broadcasting information, or for local discovery purposes.
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To communicate with a *single* destination, you need to know its public key. Any method for
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obtaining the public key is valid, but Reticulum includes a simple mechanism for making other
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nodes aware of your destinations public key, called the *announce*. It is also possible to request
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an unknown public key from the network, as all transport instances serve as a distributed ledger
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of public keys.
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Note that public key information can be shared and verified in other ways than using the
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built-in *announce* functionality, and that it is therefore not required to use the *announce* and *path request*
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functionality to obtain public keys. It is by far the easiest though, and should definitely be used
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if there is not a very good reason for doing it differently.
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.. _understanding-keyannouncements:
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Public Key Announcements
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------------------------
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An *announce* will send a special packet over any relevant interfaces, containing all needed
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information about the destination hash and public key, and can also contain some additional,
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application specific data. The entire packet is signed by the sender to ensure authenticity. It is not
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required to use the announce functionality, but in many cases it will be the simplest way to share
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public keys on the network. The announce mechanism also serves to establish end-to-end connectivity
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to the announced destination, as the announce propagates through the network.
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As an example, an announce in a simple messenger application might contain the following information:
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* The announcers destination hash
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* The announcers public key
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* Application specific data, in this case the users nickname and availability status
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* A random blob, making each new announce unique
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* An Ed25519 signature of the above information, verifying authenticity
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With this information, any Reticulum node that receives it will be able to reconstruct an outgoing
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destination to securely communicate with that destination. You might have noticed that there is one
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piece of information lacking to reconstruct full knowledge of the announced destination, and that is
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the aspect names of the destination. These are intentionally left out to save bandwidth, since they
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will be implicit in almost all cases. The receiving application will already know them. If a destination
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name is not entirely implicit, information can be included in the application specific data part that
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will allow the receiver to infer the naming.
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It is important to note that announces will be forwarded throughout the network according to a
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certain pattern. This will be detailed in the section
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:ref:`The Announce Mechanism in Detail<understanding-announce>`.
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In Reticulum, destinations are allowed to move around the network at will. This is very different from
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protocols such as IP, where an address is always expected to stay within the network segment it was assigned in.
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This limitation does not exist in Reticulum, and any destination is *completely portable* over the entire topography
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of the network, and *can even be moved to other Reticulum networks* than the one it was created in, and
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still become reachable. To update its reachability, a destination simply needs to send an announce on any
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networks it is part of. After a short while, it will be globally reachable in the network.
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Seeing how *single* destinations are always tied to a private/public key pair leads us to the next topic.
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.. _understanding-identities:
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Identities
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----------
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In Reticulum, an *identity* does not necessarily represent a personal identity, but is an abstraction that
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can represent any kind of *verifiable entity*. This could very well be a person, but it could also be the
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control interface of a machine, a program, robot, computer, sensor or something else entirely. In
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general, any kind of agent that can act, or be acted upon, or store or manipulate information, can be
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represented as an identity. An *identity* can be used to create any number of destinations.
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A *single* destination will always have an *identity* tied to it, but not *plain* or *group*
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destinations. Destinations and identities share a multilateral connection. You can create a
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destination, and if it is not connected to an identity upon creation, it will just create a new one to use
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automatically. This may be desirable in some situations, but often you will probably want to create
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the identity first, and then use it to create new destinations.
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As an example, we could use an identity to represent the user of a messaging application.
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Destinations can then be created by this identity to allow communication to reach the user.
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In all cases it is of great importance to store the private keys associated with any
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Reticulum Identity securely and privately, since obtaining access to the identity keys equals
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obtaining access and controlling reachability to any destinations created by that identity.
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.. _understanding-gettingfurther:
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Getting Further
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---------------
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The above functions and principles form the core of Reticulum, and would suffice to create
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functional networked applications in local clusters, for example over radio links where all interested
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nodes can directly hear each other. But to be truly useful, we need a way to direct traffic over multiple
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hops in the network.
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In the following sections, two concepts that allow this will be introduced, *paths* and *links*.
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.. _understanding-transport:
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Reticulum Transport
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===================
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The methods of routing used in traditional networks are fundamentally incompatible with the physical medium
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types and circumstances that Reticulum was designed to handle. These mechanisms mostly assume trust at the physical layer,
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and often needs a lot more bandwidth than Reticulum can assume is available. Since Reticulum is designed to
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survive running over open radio spectrum, no such trust can be assumed, and bandwidth is often very limited.
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To overcome such challenges, Reticulum’s *Transport* system uses asymmetric elliptic curve cryptography to
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implement the concept of *paths* that allow discovery of how to get information closer to a certain
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destination. It is important to note that no single node in a Reticulum network knows the complete
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path to a destination. Every Transport node participating in a Reticulum network will only
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know the most direct way to get a packet one hop closer to it's destination.
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.. _understanding-nodetypes:
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Node Types
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----------
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Currently, Reticulum distinguishes between two types of network nodes. All nodes on a Reticulum network
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are *Reticulum Instances*, and some are also *Transport Nodes*. If a system running Reticulum is fixed in
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one place, and is intended to be kept available most of the time, it is a good contender to be a *Transport Node*.
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Any Reticulum Instance can become a Transport Node by enabling it in the configuration.
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This distinction is made by the user configuring the node, and is used to determine what nodes on the
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network will help forward traffic, and what nodes rely on other nodes for wider connectivity.
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If a node is an *Instance* it should be given the configuration directive ``enable_transport = No``, which
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is the default setting.
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If it is a *Transport Node*, it should be given the configuration directive ``enable_transport = Yes``.
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.. _understanding-announce:
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The Announce Mechanism in Detail
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--------------------------------
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When an *announce* for a destination is transmitted by a Reticulum instance, it will be forwarded by
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any transport node receiving it, but according to some specific rules:
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* | If this exact announce has already been received before, ignore it.
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* | If not, record into a table which Transport Node the announce was received from, and how many times in
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total it has been retransmitted to get here.
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* | If the announce has been retransmitted *m+1* times, it will not be forwarded any more. By default, *m* is
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set to 128.
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* | After a randomised delay, the announce will be retransmitted on all interfaces that have bandwidth
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available for processing announces. By default, the maximum bandwidth allocation for processing
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announces is set at 2%, but can be configured on a per-interface basis.
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* | If any given interface does not have enough bandwidth available for retransmitting the announce,
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the announce will be assigned a priority inversely proportional to its hop count, and be inserted
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into a queue managed by the interface.
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* | When the interface has bandwidth available for processing an announce, it will prioritise announces
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for destinations that are closest in terms of hops, thus prioritising reachability and connectivity
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of local nodes, even on slow networks that connect to wider and faster networks.
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* | After the announce has been re-transmitted, and if no other nodes are heard retransmitting the announce
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with a greater hop count than when it left this node, transmitting it will be retried *r* times. By default,
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*r* is set to 1.
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* | If a newer announce from the same destination arrives, while an identical one is already waiting
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to be transmitted, the newest announce is discarded. If the newest announce contains different
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application specific data, it will replace the old announce.
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Once an announce has reached a node in the network, any other node in direct contact with that
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node will be able to reach the destination the announce originated from, simply by sending a packet
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addressed to that destination. Any node with knowledge of the announce will be able to direct the
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packet towards the destination by looking up the next node with the shortest amount of hops to the
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destination.
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According to these rules, an announce will propagate throughout the network in a predictable way,
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and make the announced destination reachable in a short amount of time. Fast networks that have the
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capacity to process many announces can reach full convergence very quickly, even when constantly adding
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new destinations. Slower segments of such networks might take a bit longer to gain full knowledge about
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the wide and fast networks they are connected to, but can still do so over time, while prioritising full
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||
and quickly converging end-to-end connectivity for their local, slower segments.
|
||
|
||
In general, even extremely complex networks, that utilize the maximum 128 hops will converge to full
|
||
end-to-end connectivity in about one minute, given there is enough bandwidth available to process
|
||
the required amount of announces.
|
||
|
||
.. _understanding-paths:
|
||
|
||
Reaching the Destination
|
||
------------------------
|
||
|
||
In networks with changing topology and trustless connectivity, nodes need a way to establish
|
||
*verified connectivity* with each other. Since the network is assumed to be trustless, Reticulum
|
||
must provide a way to guarantee that the peer you are communicating with is actually who you
|
||
expect. Reticulum offers two ways to do this.
|
||
|
||
For exchanges of small amounts of information, Reticulum offers the *Packet* API, which works exactly like you would expect - on a per packet level. The following process is employed when sending a packet:
|
||
|
||
* | A packet is always created with an associated destination and some payload data. When the packet is sent
|
||
to a *single* destination type, Reticulum will automatically create an ephemeral encryption key, perform
|
||
an ECDH key exchange with the destination's public key (or ratchet key, if available), and encrypt the information.
|
||
|
||
* | It is important to note that this key exchange does not require any network traffic. The sender already
|
||
knows the public key of the destination from an earlier received *announce*, and can thus perform the ECDH
|
||
key exchange locally, before sending the packet.
|
||
|
||
* | The public part of the newly generated ephemeral key-pair is included with the encrypted token, and sent
|
||
along with the encrypted payload data in the packet.
|
||
|
||
* | When the destination receives the packet, it can itself perform an ECDH key exchange and decrypt the
|
||
packet.
|
||
|
||
* | A new ephemeral key is used for every packet sent in this way.
|
||
|
||
* | Once the packet has been received and decrypted by the addressed destination, that destination can opt
|
||
to *prove* its receipt of the packet. It does this by calculating the SHA-256 hash of the received packet,
|
||
and signing this hash with its Ed25519 signing key. Transport nodes in the network can then direct this
|
||
*proof* back to the packets origin, where the signature can be verified against the destination's known
|
||
public signing key.
|
||
|
||
* | In case the packet is addressed to a *group* destination type, the packet will be encrypted with the
|
||
pre-shared AES-128 key associated with the destination. In case the packet is addressed to a *plain*
|
||
destination type, the payload data will not be encrypted. Neither of these two destination types can offer
|
||
forward secrecy. In general, it is recommended to always use the *single* destination type, unless it is
|
||
strictly necessary to use one of the others.
|
||
|
||
|
||
For exchanges of larger amounts of data, or when longer sessions of bidirectional communication is desired, Reticulum offers the *Link* API. To establish a *link*, the following process is employed:
|
||
|
||
* | First, the node that wishes to establish a link will send out a special packet, that
|
||
traverses the network and locates the desired destination. Along the way, the Transport Nodes that
|
||
forward the packet will take note of this *link request*.
|
||
|
||
* | Second, if the destination accepts the *link request* , it will send back a packet that proves the
|
||
authenticity of its identity (and the receipt of the link request) to the initiating node. All
|
||
nodes that initially forwarded the packet will also be able to verify this proof, and thus
|
||
accept the validity of the *link* throughout the network.
|
||
|
||
* | When the validity of the *link* has been accepted by forwarding nodes, these nodes will
|
||
remember the *link* , and it can subsequently be used by referring to a hash representing it.
|
||
|
||
* | As a part of the *link request*, an Elliptic Curve Diffie-Hellman key exchange takes place, that sets up an
|
||
efficiently encrypted tunnel between the two nodes. As such, this mode of communication is preferred,
|
||
even for situations when nodes can directly communicate, when the amount of data to be exchanged numbers
|
||
in the tens of packets, or whenever the use of the more advanced API functions is desired.
|
||
|
||
* | When a *link* has been set up, it automatically provides message receipt functionality, through
|
||
the same *proof* mechanism discussed before, so the sending node can obtain verified confirmation
|
||
that the information reached the intended recipient.
|
||
|
||
* | Once the *link* has been set up, the initiator can remain anonymous, or choose to authenticate towards
|
||
the destination using a Reticulum Identity. This authentication is happening inside the encrypted
|
||
link, and is only revealed to the verified destination, and no intermediaries.
|
||
|
||
In a moment, we will discuss the details of how this methodology is
|
||
implemented, but let’s first recap what purposes this methodology serves. We
|
||
first ensure that the node answering our request is actually the one we want to
|
||
communicate with, and not a malicious actor pretending to be so. At the same
|
||
time we establish an efficient encrypted channel. The setup of this is
|
||
relatively cheap in terms of bandwidth, so it can be used just for a short
|
||
exchange, and then recreated as needed, which will also rotate encryption keys.
|
||
The link can also be kept alive for longer periods of time, if this is more
|
||
suitable to the application. The procedure also inserts the *link id* , a hash
|
||
calculated from the link request packet, into the memory of forwarding nodes,
|
||
which means that the communicating nodes can thereafter reach each other simply
|
||
by referring to this *link id*.
|
||
|
||
The combined bandwidth cost of setting up a link is 3 packets totalling 297 bytes (more info in the
|
||
:ref:`Binary Packet Format<understanding-packetformat>` section). The amount of bandwidth used on keeping
|
||
a link open is practically negligible, at 0.45 bits per second. Even on a slow 1200 bits per second packet
|
||
radio channel, 100 concurrent links will still leave 96% channel capacity for actual data.
|
||
|
||
|
||
Link Establishment in Detail
|
||
^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
||
|
||
After exploring the basics of the announce mechanism, finding a path through the network, and an overview
|
||
of the link establishment procedure, this section will go into greater detail about the Reticulum link
|
||
establishment process.
|
||
|
||
The *link* in Reticulum terminology should not be viewed as a direct node-to-node link on the
|
||
physical layer, but as an abstract channel, that can be open for any amount of time, and can span
|
||
an arbitrary number of hops, where information will be exchanged between two nodes.
|
||
|
||
|
||
* | When a node in the network wants to establish verified connectivity with another node, it
|
||
will randomly generate a new X25519 private/public key pair. It then creates a *link request*
|
||
packet, and broadcast it.
|
||
|
|
||
| *It should be noted that the X25519 public/private keypair mentioned above is two separate keypairs:
|
||
An encryption key pair, used for derivation of a shared symmetric key, and a signing key pair, used
|
||
for signing and verifying messages on the link. They are sent together over the wire, and can be
|
||
considered as single public key for simplicity in this explanation.*
|
||
|
||
* | The *link request* is addressed to the destination hash of the desired destination, and
|
||
contains the following data: The newly generated X25519 public key *LKi*.
|
||
|
||
* | The broadcasted packet will be directed through the network according to the rules laid out
|
||
previously.
|
||
|
||
* | Any node that forwards the link request will store a *link id* in it’s *link table* , along with the
|
||
amount of hops the packet had taken when received. The link id is a hash of the entire link
|
||
request packet. If the link request packet is not *proven* by the addressed destination within some
|
||
set amount of time, the entry will be dropped from the *link table* again.
|
||
|
||
* | When the destination receives the link request packet, it will decide whether to accept the request.
|
||
If it is accepted, the destination will also generate a new X25519 private/public key pair, and
|
||
perform a Diffie Hellman Key Exchange, deriving a new symmetric key that will be used to encrypt the
|
||
channel, once it has been established.
|
||
|
||
* | A *link proof* packet is now constructed and transmitted over the network. This packet is
|
||
addressed to the *link id* of the *link*. It contains the following data: The newly generated X25519
|
||
public key *LKr* and an Ed25519 signature of the *link id* and *LKr* made by the *original signing key* of
|
||
the addressed destination.
|
||
|
||
* | By verifying this *link proof* packet, all nodes that originally transported the *link request*
|
||
packet to the destination from the originator can now verify that the intended destination received
|
||
the request and accepted it, and that the path they chose for forwarding the request was valid.
|
||
In successfully carrying out this verification, the transporting nodes marks the link as active.
|
||
An abstract bi-directional communication channel has now been established along a path in the network.
|
||
Packets can now be exchanged bi-directionally from either end of the link simply by adressing the
|
||
packets to the *link id* of the link.
|
||
|
||
* | When the source receives the *proof* , it will know unequivocally that a verified path has been
|
||
established to the destination. It can now also use the X25519 public key contained in the
|
||
*link proof* to perform it's own Diffie Hellman Key Exchange and derive the symmetric key
|
||
that is used to encrypt the channel. Information can now be exchanged reliably and securely.
|
||
|
||
|
||
It’s important to note that this methodology ensures that the source of the request does not need to
|
||
reveal any identifying information about itself. The link initiator remains completely anonymous.
|
||
|
||
When using *links*, Reticulum will automatically verify all data sent over the link, and can also
|
||
automate retransmissions if *Resources* are used.
|
||
|
||
.. _understanding-resources:
|
||
|
||
Resources
|
||
---------
|
||
|
||
For exchanging small amounts of data over a Reticulum network, the :ref:`Packet<api-packet>` interface
|
||
is sufficient, but for exchanging data that would require many packets, an efficient way to coordinate
|
||
the transfer is needed.
|
||
|
||
This is the purpose of the Reticulum :ref:`Resource<api-resource>`. A *Resource* can automatically
|
||
handle the reliable transfer of an arbitrary amount of data over an established :ref:`Link<api-link>`.
|
||
Resources can auto-compress data, will handle breaking the data into individual packets, sequencing
|
||
the transfer, integrity verification and reassembling the data on the other end.
|
||
|
||
:ref:`Resources<api-resource>` are programmatically very simple to use, and only requires a few lines
|
||
of codes to reliably transfer any amount of data. They can be used to transfer data stored in memory,
|
||
or stream data directly from files.
|
||
|
||
.. _understanding-referencesystem:
|
||
|
||
Reference Setup
|
||
======================
|
||
|
||
This section will detail a recommended *Reference Setup* for Reticulum. It is important to
|
||
note that Reticulum is designed to be usable on more or less any computing device, and over more
|
||
or less any medium that allows you to send and receive data, which satisfies some very low
|
||
minimum requirements.
|
||
|
||
The communication channel must support at least half-duplex operation, and provide an average
|
||
throughput of 5 bits per second or greater, and supports a physical layer MTU of 500 bytes. The
|
||
Reticulum stack should be able to run on more or less any hardware that can provide a Python 3.x
|
||
runtime environment.
|
||
|
||
That being said, this reference setup has been outlined to provide a common platform for anyone
|
||
who wants to help in the development of Reticulum, and for everyone who wants to know a
|
||
recommended setup to get started experimenting. A reference system consists of three parts:
|
||
|
||
* **An Interface Device**
|
||
Which provides access to the physical medium whereupon the communication
|
||
takes place, for example a radio with an integrated modem. A setup with a separate modem
|
||
connected to a radio would also be an interface device.
|
||
* **A Host Device**
|
||
Some sort of computing device that can run the necessary software, communicate with the
|
||
interface device, and provide user interaction.
|
||
* **A Software Stack**
|
||
The software implementing the Reticulum protocol and applications using it.
|
||
|
||
The reference setup can be considered a relatively stable platform to develop on, and also to start
|
||
building networks or applications on. While details of the implementation might change at the current stage of
|
||
development, it is the goal to maintain hardware compatibility for as long as entirely possible, and
|
||
the current reference setup has been determined to provide a functional platform for many years
|
||
into the future. The current Reference System Setup is as follows:
|
||
|
||
|
||
* **Interface Device**
|
||
A data radio consisting of a LoRa radio module, and a microcontroller with open source
|
||
firmware, that can connect to host devices via USB. It operates in either the 430, 868 or 900
|
||
MHz frequency bands. More details can be found on the `RNode Page <https://unsigned.io/rnode>`_.
|
||
* **Host Device**
|
||
Any computer device running Linux and Python. A Raspberry Pi with a Debian based OS is
|
||
recommended.
|
||
* **Software Stack**
|
||
The most recently released Python Implementation of Reticulum, running on a Debian based
|
||
operating system.
|
||
|
||
To avoid confusion, it is very important to note, that the reference interface device **does not**
|
||
use the LoRaWAN standard, but uses a custom MAC layer on top of the plain LoRa modulation! As such, you will
|
||
need a plain LoRa radio module connected to an controller with the correct firmware. Full details on how to
|
||
get or make such a device is available on the `RNode Page <https://unsigned.io/rnode>`_.
|
||
|
||
With the current reference setup, it should be possible to get on a Reticulum network for around 100$
|
||
even if you have none of the hardware already, and need to purchase everything.
|
||
|
||
This reference setup is of course just a recommendation for getting started easily, and you should
|
||
tailor it to your own specific needs, or whatever hardware you have available.
|
||
|
||
.. _understanding-protocolspecifics:
|
||
|
||
Protocol Specifics
|
||
==================
|
||
|
||
This chapter will detail protocol specific information that is essential to the implementation of
|
||
Reticulum, but non critical in understanding how the protocol works on a general level. It should be
|
||
treated more as a reference than as essential reading.
|
||
|
||
|
||
Packet Prioritisation
|
||
---------------------
|
||
|
||
Currently, Reticulum is completely priority-agnostic regarding general traffic. All traffic is handled
|
||
on a first-come, first-serve basis. Announce re-transmission are handled according to the re-transmission
|
||
times and priorities described earlier in this chapter.
|
||
|
||
|
||
Interface Access Codes
|
||
----------------------
|
||
|
||
Reticulum can create named virtual networks, and networks that are only accessible by knowing a preshared
|
||
passphrase. The configuration of this is detailed in the :ref:`Common Interface Options<interfaces-options>`
|
||
section. To implement these feature, Reticulum uses the concept of Interface Access Codes, that are calculated
|
||
and verified per packet.
|
||
|
||
An interface with a named virtual network or passphrase authentication enabled will derive a shared Ed25519
|
||
signing identity, and for every outbound packet generate a signature of the entire packet. This signature is
|
||
then inserted into the packet as an Interface Access Code before transmission. Depending on the speed and
|
||
capabilities of the interface, the IFAC can be the full 512-bit Ed25519 signature, or a truncated version.
|
||
Configured IFAC length can be inspected for all interfaces with the ``rnstatus`` utility.
|
||
|
||
Upon receipt, the interface will check that the signature matches the expected value, and drop the packet if it
|
||
does not. This ensures that only packets sent with the correct naming and/or passphrase parameters are allowed to
|
||
pass onto the network.
|
||
|
||
|
||
.. _understanding-packetformat:
|
||
|
||
Wire Format
|
||
-----------
|
||
|
||
.. code-block:: text
|
||
|
||
== Reticulum Wire Format ======
|
||
|
||
A Reticulum packet is composed of the following fields:
|
||
|
||
[HEADER 2 bytes] [ADDRESSES 16/32 bytes] [CONTEXT 1 byte] [DATA 0-465 bytes]
|
||
|
||
* The HEADER field is 2 bytes long.
|
||
* Byte 1: [IFAC Flag], [Header Type], [Context Flag], [Propagation Type],
|
||
[Destination Type] and [Packet Type]
|
||
* Byte 2: Number of hops
|
||
|
||
* Interface Access Code field if the IFAC flag was set.
|
||
* The length of the Interface Access Code can vary from
|
||
1 to 64 bytes according to physical interface
|
||
capabilities and configuration.
|
||
|
||
* The ADDRESSES field contains either 1 or 2 addresses.
|
||
* Each address is 16 bytes long.
|
||
* The Header Type flag in the HEADER field determines
|
||
whether the ADDRESSES field contains 1 or 2 addresses.
|
||
* Addresses are SHA-256 hashes truncated to 16 bytes.
|
||
|
||
* The CONTEXT field is 1 byte.
|
||
* It is used by Reticulum to determine packet context.
|
||
|
||
* The DATA field is between 0 and 465 bytes.
|
||
* It contains the packets data payload.
|
||
|
||
IFAC Flag
|
||
-----------------
|
||
open 0 Packet for publically accessible interface
|
||
authenticated 1 Interface authentication is included in packet
|
||
|
||
|
||
Header Types
|
||
-----------------
|
||
type 1 0 Two byte header, one 16 byte address field
|
||
type 2 1 Two byte header, two 16 byte address fields
|
||
|
||
|
||
Context Flag
|
||
-----------------
|
||
unset 0 The context flag is used for various types
|
||
set 1 of signalling, depending on packet context
|
||
|
||
|
||
Propagation Types
|
||
-----------------
|
||
broadcast 0
|
||
transport 1
|
||
|
||
|
||
Destination Types
|
||
-----------------
|
||
single 00
|
||
group 01
|
||
plain 10
|
||
link 11
|
||
|
||
|
||
Packet Types
|
||
-----------------
|
||
data 00
|
||
announce 01
|
||
link request 10
|
||
proof 11
|
||
|
||
|
||
+- Packet Example -+
|
||
|
||
HEADER FIELD DESTINATION FIELDS CONTEXT FIELD DATA FIELD
|
||
_______|_______ ________________|________________ ________|______ __|_
|
||
| | | | | | | |
|
||
01010000 00000100 [HASH1, 16 bytes] [HASH2, 16 bytes] [CONTEXT, 1 byte] [DATA]
|
||
|| | | | |
|
||
|| | | | +-- Hops = 4
|
||
|| | | +------- Packet Type = DATA
|
||
|| | +--------- Destination Type = SINGLE
|
||
|| +----------- Propagation Type = TRANSPORT
|
||
|+------------- Header Type = HEADER_2 (two byte header, two address fields)
|
||
+-------------- Access Codes = DISABLED
|
||
|
||
|
||
+- Packet Example -+
|
||
|
||
HEADER FIELD DESTINATION FIELD CONTEXT FIELD DATA FIELD
|
||
_______|_______ _______|_______ ________|______ __|_
|
||
| | | | | | | |
|
||
00000000 00000111 [HASH1, 16 bytes] [CONTEXT, 1 byte] [DATA]
|
||
|| | | | |
|
||
|| | | | +-- Hops = 7
|
||
|| | | +------- Packet Type = DATA
|
||
|| | +--------- Destination Type = SINGLE
|
||
|| +----------- Propagation Type = BROADCAST
|
||
|+------------- Header Type = HEADER_1 (two byte header, one address field)
|
||
+-------------- Access Codes = DISABLED
|
||
|
||
|
||
+- Packet Example -+
|
||
|
||
HEADER FIELD IFAC FIELD DESTINATION FIELD CONTEXT FIELD DATA FIELD
|
||
_______|_______ ______|______ _______|_______ ________|______ __|_
|
||
| | | | | | | | | |
|
||
10000000 00000111 [IFAC, N bytes] [HASH1, 16 bytes] [CONTEXT, 1 byte] [DATA]
|
||
|| | | | |
|
||
|| | | | +-- Hops = 7
|
||
|| | | +------- Packet Type = DATA
|
||
|| | +--------- Destination Type = SINGLE
|
||
|| +----------- Propagation Type = BROADCAST
|
||
|+------------- Header Type = HEADER_1 (two byte header, one address field)
|
||
+-------------- Access Codes = ENABLED
|
||
|
||
|
||
Size examples of different packet types
|
||
---------------------------------------
|
||
|
||
The following table lists example sizes of various
|
||
packet types. The size listed are the complete on-
|
||
wire size counting all fields including headers,
|
||
but excluding any interface access codes.
|
||
|
||
- Path Request : 51 bytes
|
||
- Announce : 167 bytes
|
||
- Link Request : 83 bytes
|
||
- Link Proof : 115 bytes
|
||
- Link RTT packet : 99 bytes
|
||
- Link keepalive : 20 bytes
|
||
|
||
|
||
.. _understanding-announcepropagation:
|
||
|
||
Announce Propagation Rules
|
||
--------------------------
|
||
|
||
The following table illustrates the rules for automatically propagating announces
|
||
from one interface type to another, for all possible combinations. For the purpose
|
||
of announce propagation, the *Full* and *Gateway* modes are identical.
|
||
|
||
.. image:: graphics/if_mode_graph_b.png
|
||
|
||
See the :ref:`Interface Modes<interfaces-modes>` section for a conceptual overview
|
||
of the different interface modes, and how they are configured.
|
||
|
||
..
|
||
(.. code-block:: text)
|
||
Full ────── ✓ ──┐ ┌── ✓ ── Full
|
||
AP ──────── ✓ ──┼───> Full >───┼── ✕ ── AP
|
||
Boundary ── ✓ ──┤ ├── ✓ ── Boundary
|
||
Roaming ─── ✓ ──┘ └── ✓ ── Roaming
|
||
|
||
Full ────── ✕ ──┐ ┌── ✓ ── Full
|
||
AP ──────── ✕ ──┼────> AP >────┼── ✕ ── AP
|
||
Boundary ── ✕ ──┤ ├── ✓ ── Boundary
|
||
Roaming ─── ✕ ──┘ └── ✓ ── Roaming
|
||
|
||
Full ────── ✓ ──┐ ┌── ✓ ── Full
|
||
AP ──────── ✓ ──┼─> Roaming >──┼── ✕ ── AP
|
||
Boundary ── ✕ ──┤ ├── ✕ ── Boundary
|
||
Roaming ─── ✕ ──┘ └── ✕ ── Roaming
|
||
|
||
Full ────── ✓ ──┐ ┌── ✓ ── Full
|
||
AP ──────── ✓ ──┼─> Boundary >─┼── ✕ ── AP
|
||
Boundary ── ✓ ──┤ ├── ✓ ── Boundary
|
||
Roaming ─── ✕ ──┘ └── ✕ ── Roaming
|
||
|
||
|
||
.. _understanding-primitives:
|
||
|
||
Cryptographic Primitives
|
||
------------------------
|
||
|
||
Reticulum has been designed to use a simple suite of efficient, strong and modern
|
||
cryptographic primitives, with widely available implementations that can be used
|
||
both on general-purpose CPUs and on microcontrollers. The necessary primitives are:
|
||
|
||
* Ed25519 for signatures
|
||
|
||
* X25519 for ECDH key exchanges
|
||
|
||
* HKDF for key derivation
|
||
|
||
* Encrypted tokens are based on the Fernet spec
|
||
|
||
* Ephemeral keys derived from an ECDH key exchange on Curve25519
|
||
|
||
* AES-128 in CBC mode with PKCS7 padding
|
||
|
||
* HMAC using SHA256 for message authentication
|
||
|
||
* IVs are generated through os.urandom()
|
||
|
||
* No Fernet version and timestamp metadata fields
|
||
|
||
* SHA-256
|
||
|
||
* SHA-512
|
||
|
||
In the default installation configuration, the ``X25519``, ``Ed25519`` and ``AES-128-CBC``
|
||
primitives are provided by `OpenSSL <https://www.openssl.org/>`_ (via the `PyCA/cryptography <https://github.com/pyca/cryptography>`_
|
||
package). The hashing functions ``SHA-256`` and ``SHA-512`` are provided by the standard
|
||
Python `hashlib <https://docs.python.org/3/library/hashlib.html>`_. The ``HKDF``, ``HMAC``,
|
||
``Token`` primitives, and the ``PKCS7`` padding function are always provided by the
|
||
following internal implementations:
|
||
|
||
- ``RNS/Cryptography/HKDF.py``
|
||
- ``RNS/Cryptography/HMAC.py``
|
||
- ``RNS/Cryptography/Token.py``
|
||
- ``RNS/Cryptography/PKCS7.py``
|
||
|
||
|
||
Reticulum also includes a complete implementation of all necessary primitives in pure Python.
|
||
If OpenSSL & PyCA are not available on the system when Reticulum is started, Reticulum will
|
||
instead use the internal pure-python primitives. A trivial consequence of this is performance,
|
||
with the OpenSSL backend being *much* faster. The most important consequence however, is the
|
||
potential loss of security by using primitives that has not seen the same amount of scrutiny,
|
||
testing and review as those from OpenSSL.
|
||
|
||
If you want to use the internal pure-python primitives, it is **highly advisable** that you
|
||
have a good understanding of the risks that this pose, and make an informed decision on whether
|
||
those risks are acceptable to you.
|