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Author SHA1 Message Date
markqvist
3b2fbe02c6
Merge pull request #189 from Erethon/master
Fix bug where announce_identity could be undefined
2023-02-02 10:41:42 +01:00
markqvist
a38bde7801
Merge pull request #191 from Erethon/packet-header-fix
packet: Fix header_type matching according to IFAC
2023-02-02 10:22:44 +01:00
markqvist
df132d1d59
Merge pull request #199 from Erethon/doc-fixes
docs: Fix typos, remove old info about rnsconfig
2023-02-02 10:16:13 +01:00
Dionysis Grigoropoulos
feb614d186 docs: Fix typos, remove old info about rnsconfig 2023-02-01 22:30:56 +02:00
Dionysis Grigoropoulos
6ecae615de packet: Fix header_type matching according to IFAC
Ever since IFAC/Interface Access Codes were introduced, the header type
is one bit long and not two.
2023-01-27 15:29:06 +02:00
Dionysis Grigoropoulos
72ca6316f6 Fix bug where announce_identity could be undefined 2023-01-26 22:05:38 +02:00
4 changed files with 16 additions and 18 deletions

View File

@ -58,9 +58,7 @@ class Packet:
# Header types
HEADER_1 = 0x00 # Normal header format
HEADER_2 = 0x01 # Header format used for packets in transport
HEADER_3 = 0x02 # Reserved
HEADER_4 = 0x03 # Reserved
header_types = [HEADER_1, HEADER_2, HEADER_3, HEADER_4]
header_types = [HEADER_1, HEADER_2]
# Packet context types
NONE = 0x00 # Generic data packet
@ -215,7 +213,7 @@ class Packet:
self.flags = self.raw[0]
self.hops = self.raw[1]
self.header_type = (self.flags & 0b11000000) >> 6
self.header_type = (self.flags & 0b01000000) >> 6
self.transport_type = (self.flags & 0b00110000) >> 4
self.destination_type = (self.flags & 0b00001100) >> 2
self.packet_type = (self.flags & 0b00000011)

View File

@ -1427,12 +1427,12 @@ class Transport:
# Check that the announced destination matches
# the handlers aspect filter
execute_callback = False
announce_identity = RNS.Identity.recall(packet.destination_hash)
if handler.aspect_filter == None:
# If the handlers aspect filter is set to
# None, we execute the callback in all cases
execute_callback = True
else:
announce_identity = RNS.Identity.recall(packet.destination_hash)
handler_expected_hash = RNS.Destination.hash_from_name_and_identity(handler.aspect_filter, announce_identity)
if packet.destination_hash == handler_expected_hash:
execute_callback = True

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@ -115,8 +115,8 @@ Creating a Network With Reticulum
=============================================
To create a network, you will need to specify one or more *interfaces* for
Reticulum to use. This is done in the Reticulum configuration file, which by
default is located at ``~/.reticulum/config``. You can edit this file by hand,
or use the interactive ``rnsconfig`` utility.
default is located at ``~/.reticulum/config``. You can get an example
configuration file with all options via ``rnsd --exampleconfig``.
When Reticulum is started for the first time, it will create a default
configuration file, with one active interface. This default interface uses

View File

@ -107,13 +107,13 @@ guide the design of Reticulum:
Introduction & Basic Functionality
==================================
Reticulum is a networking stack suited for high-latency, low-bandwidth links. Reticulum is at its
Reticulum is a networking stack suited for high-latency, low-bandwidth links. Reticulum is at its
core a *message oriented* system. It is suited for both local point-to-point or point-to-multipoint
scenarios where all nodes are within range of each other, as well as scenarios where packets need
to be transported over multiple hops in a complex network to reach the recipient.
Reticulum does away with the idea of addresses and ports known from IP, TCP and UDP. Instead
Reticulum uses the singular concept of *destinations*. Any application using Reticulum as its
Reticulum uses the singular concept of *destinations*. Any application using Reticulum as its
networking stack will need to create one or more destinations to receive data, and know the
destinations it needs to send data to.
@ -220,7 +220,7 @@ packet.
In actual use of *single* destination naming, it is advisable not to use any uniquely identifying
features in aspect naming. Aspect names should be general terms describing what kind of destination
is represented. The uniquely identifying aspect is always achieved by the appending the public key,
is represented. The uniquely identifying aspect is always achieved by appending the public key,
which expands the destination into a uniquely identifiable one. Reticulum does this automatically.
Any destination on a Reticulum network can be addressed and reached simply by knowing its
@ -239,7 +239,7 @@ To recap, the different destination types should be used in the following situat
* **Plain**
When plain-text communication is desirable, for example when broadcasting information, or for local discovery purposes.
To communicate with a *single* destination, you need to know its public key. Any method for
To communicate with a *single* destination, you need to know its public key. Any method for
obtaining the public key is valid, but Reticulum includes a simple mechanism for making other
nodes aware of your destinations public key, called the *announce*. It is also possible to request
an unknown public key from the network, as all transport instances serve as a distributed ledger
@ -287,7 +287,7 @@ In Reticulum, destinations are allowed to move around the network at will. This
protocols such as IP, where an address is always expected to stay within the network segment it was assigned in.
This limitation does not exist in Reticulum, and any destination is *completely portable* over the entire topography
of the network, and *can even be moved to other Reticulum networks* than the one it was created in, and
still become reachable. To update it's reachability, a destination simply needs to send an announce on any
still become reachable. To update its reachability, a destination simply needs to send an announce on any
networks it is part of. After a short while, it will be globally reachable in the network.
Seeing how *single* destinations are always tied to a private/public key pair leads us to the next topic.
@ -368,7 +368,7 @@ If it is a *Transport Node*, it should be given the configuration directive ``en
The Announce Mechanism in Detail
--------------------------------
When an *announce* for a destination is transmitted by from a Reticulum instance, it will be forwarded by
When an *announce* for a destination is transmitted by a Reticulum instance, it will be forwarded by
any transport node receiving it, but according to some specific rules:
@ -385,7 +385,7 @@ any transport node receiving it, but according to some specific rules:
announces is set at 2%, but can be configured on a per-interface basis.
* | If any given interface does not have enough bandwidth available for retransmitting the announce,
the announce will be assigned a priority inversely proportional to it's hop count, and be inserted
the announce will be assigned a priority inversely proportional to its hop count, and be inserted
into a queue managed by the interface.
* | When the interface has bandwidth available for processing an announce, it will prioritise announces
@ -431,7 +431,7 @@ For exchanges of small amounts of information, Reticulum offers the *Packet* API
* | 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 destinations public key, and encrypt the information.
an ECDH key exchange with the destination's public key, 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
@ -447,8 +447,8 @@ For exchanges of small amounts of information, Reticulum offers the *Packet* API
* | 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 it's 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 destinations known
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
@ -465,7 +465,7 @@ For exchanges of larger amounts of data, or when longer sessions of bidirectiona
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
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.