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742 lines
17 KiB
Plaintext
742 lines
17 KiB
Plaintext
LLARP v0
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LLARP (Low Latency Anon Routing Protocol) is a protocol for anonymizing senders and
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recipiants of encrypted messages sent over the internet without a centralied
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trusted party.
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The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
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"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
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document are to be interpreted as described in RFC 2119 [RFC2119].
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basic structures:
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all structures are key, value dictionaries encoded with bittorrent encoding
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notation:
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a + b is a concatanated with b
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a ^ b is a bitwise XOR b
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x[a:b] is a memory slice of x from index a to b
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BE(x) is bittorrent encode x
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BD(x) is bittorrent decode x
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{ a: b, y: z } is a dictionary with two keys a and y
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who's values are b and z respectively
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[ a, b, c ... ] is a list containing a b c and more items in that order
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"<description>" is a bytestring who's contents and length is described by the
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quoted value <description>
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"<value>" * N is a bytestring containing the <value> concatenated N times.
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cryptography:
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see crypto_v0.txt
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---
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wire protocol
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see iwp-v0.txt
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---
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datastructures:
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all datastructures are assumed version 0 if they lack a v value
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otherwise version is provided by the v value
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all ip addresses can be ipv4 via hybrid dual stack ipv4 mapped ipv6 addresses,
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i.e ::ffff.8.8.8.8. The underlying implementation MAY implement ipv4 as native
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ipv4 instead of using a hybrid dual stack.
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net address:
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net addresses are a variable length byte string, if between 7 and 15 bytes it's
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treated as a dot notation ipv4 address (xxx.xxx.xxx.xxx)
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if it's exactly 16 bytes it's treated as a big endian encoding ipv6 address.
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address info (AI)
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An address info (AI) defines a publically reachable endpoint
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{
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c: transport_rank_uint16,
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d: "<transport dialect name>",
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e: "<32 bytes public encryption key>",
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i: "<net address>",
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p: port_uint16,
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v: 0
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}
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example iwp address info:
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{
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c: 1,
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d: "iwp",
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e: "<32 bytes of 0x61>",
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i: "123.123.123.123",
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p: 1234,
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v: 0
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}
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bencoded form:
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d1:ci1e1:d3:iwp1:e32:aaaaaaaaaaaaaaaaaaaaaaaaaaaaaaaa1:d3:iwp1:i15:123.123.123.1231:pi1234e1:vi0ee
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Exit Info (XI)
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An exit info (XI) defines a exit address that can relay exit traffic to the
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internet.
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{
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a: "<net address exit address>",
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b: "<net address exit netmask>",
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k: "<32 bytes public encryption/signing key>",
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v: 0
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}
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Exit Route (XR)
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An exit route (XR) define an allocated exit address and any additional
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information required to access the internet via that exit address.
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{
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a: "<16 bytes big endian ipv6 gateway address>",
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b: "<16 bytes big endian ipv6 netmask>",
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c: "<16 bytes big endian ipv6 source address>",
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l: lifetime_in_seconds_uint64,
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v: 0
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}
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router contact (RC)
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router's full identity
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{
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a: [ one, or, many, AI, here ... ],
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k: "<32 bytes public long term identity signing key>",
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n: "<optional max 32 bytes router nickname>",
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p: "<32 bytes public path encryption key>",
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u: last_updated_seconds_since_epoch_uint64,
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v: 0,
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x: [ Exit, Infos ],
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z: "<64 bytes signature using identity key>"
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}
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service info (SI)
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public information blob for a hidden service
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e is the long term public encryption key
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s is the long term public signing key
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v is the protocol version
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x is a nounce value for generating vanity addresses that can be omitted
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if x is included it MUST be equal to 16 bytes
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{
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e: "<32 bytes public encryption key>",
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s: "<32 bytes public signing key>",
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v: 0,
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x: "<optional 16 bytes nonce for vanity>"
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}
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service address (SA)
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the "network address" of a hidden service, which is computed as the blake2b
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256 bit hash of the public infomration blob.
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HS(BE(SI))
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when in string form it's encoded with z-base32 and uses the .loki tld
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introduction (I)
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a descriptor annoucing a path to a hidden service
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k is the rc.k value of the router to contact
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p is the path id on the router that is owned by the service
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v is the protocol version
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x is the timestamp seconds since epoch that this introduction expires at
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{
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k: "<32 bytes public identity key of router>",
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l: advertised_path_latency_ms_uint64, (optional)
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p: "<16 bytes path id>",
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v: 0,
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x: time_expires_seconds_since_epoch_uint64
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}
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introduction set (IS)
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a signed set of introductions for a hidden service
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a is the service info of the publisher
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i is the list of introductions that this service is advertising with
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k is the public key to use when doing encryption to this hidden service
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n is a 16 byte null padded utf-8 encoded string tagging the hidden service in
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a topic searchable via a lookup (optional)
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v is the protocol version
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w is an optinal proof of work for DoS protection (slot for future)
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z is the signature of the entire IS where z is set to zero signed by the hidden
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service's signing key.
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{
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a: SI,
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i: [ I, I, I, ... ],
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k: "<1218 bytes sntrup4591761 public key block>",
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n: "<16 bytes service topic (optional)>",
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v: 0,
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w: optional proof of work,
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z: "<64 bytes signature using service info signing key>"
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}
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---
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Encrypted frames:
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Encrypted frames are encrypted containers for link message records like LRCR.
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32 bytes hmac, h
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32 bytes nounce, n
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32 bytes ephmeral sender's public encryption key, k
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remaining bytes ciphertext, x
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decryption:
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0) verify hmac
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S = PKE(n, k, our_RC.K)
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verify h == MDS(n + k + x, S)
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If the hmac verification fails the entire parent message is discarded
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1) decrypt and decode
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new_x = SD(S, n[0:24], x)
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msg = BD(new_x)
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If the decoding fails the entire parent message is discarded
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encryption:
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to encrypt a frame to a router with public key B.k
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0) prepare nounce n, ephemeral keypair (A.k, s) and derive shared secret S
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A.k, s = ECKG()
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n = RAND(32)
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S = PKE(p, A.k, B.k, n)
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1) encode and encrypt
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x = BE(msg)
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new_x = SE(S, n[0:24], x)
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2) generate message authentication
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h = MDS(n + A.k + new_x, S)
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resulting frame is h + n + A.k + new_x
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---
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link layer messages:
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the link layer is responsible for anonymising the source and destination of
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routing layer messages.
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any link layer message without a key v is assumed to be version 0 otherwise
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indicates the protocol version in use.
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link introduce message (LIM)
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This message MUST be the first link message sent before any others. This message
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identifies the sender as having the RC contained in r. The recipiant MUST
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validate the RC's signature and ensure that the public key in use is listed in
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the RC.a matching the ipv6 address it originated from.
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{
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a: "i",
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n: "<32 bytes nonce for key exhcange>",
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p: uint64_milliseconds_session_period,
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r: RC,
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v: 0,
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z: "<64 bytes signature of entire message by r.k>"
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}
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the link session will be kept open for p milliseconds after which
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the session MUST be renegotiated.
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link relay commit message (LRCM)
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request a commit to relay traffic to another node.
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{
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a: "c",
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c: [ list, of, encrypted, frames ],
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v: 0
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}
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c and r MUST contain dummy records if the hop length is less than the maximum
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hop length.
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link relay commit record (LRCR)
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record requesting relaying messages for 600 seconds to router
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on network who's i is equal to RC.k and decrypt data any messages using
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PKE(n, rc.K, c) as symettric key for encryption and decryption.
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if l is provided and is less than 600 and greater than 10 then that lifespan
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is used (in seconds) instead of 600 seconds.
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if w is provided and fits the required proof of work then the lifetime of
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the path is extended by w.y seconds
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{
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c: "<32 byte public encryption key used for upstream>",
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i: "<32 byte RC.k of next hop>",
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l: uint_optional_lifespan,
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n: "<32 bytes nounce for key exchange>",
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r: "<16 bytes rx path id>",
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t: "<16 bytes tx path id>",
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v: 0,
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w: proof of work
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}
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w if provided is a dict with the following struct
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{
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t: time_created_seconds_since_epoch,
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v: 0,
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y: uint32_seconds_extended_lifetime,
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z: "<32 bytes nonce>"
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}
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the validity of the proof of work is that given
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h = HS(BE(w))
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h has log_e(y) prefixed bytes being 0x00
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this proof of work requirement is subject to change
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if i is equal to RC.k then any LRDM.x values are decrypted and interpreted as
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routing layer messages. This indicates that we are the farthest hop in the path.
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link relay upstream message (LRUM)
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sent to relay data via upstream direction of a previously created path.
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{
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a: "u",
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p: "<16 bytes path id>",
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v: 0,
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x: "<N bytes encrypted x1 value>",
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y: "<32 bytes nonce>"
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}
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x1 = SD(k, y, x)
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if we are the farthest hop, process x1 as a routing message
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otherwise transmit a LRUM to the next hop
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{
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a: "u",
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p: p,
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v: 0,
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x: x1,
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y: y ^ HS(k)
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}
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link relay downstream message (LRDM)
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sent to relay data via downstream direction of a previously created path.
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{
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a: "d",
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p: "<16 bytes path id>",
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v: 0,
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x: "<N bytes encrypted x1 value>",
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y: "<32 bytes nonce>"
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}
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if we are the creator of the path decrypt x for each hop key k
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x = SD(k, y, x)
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otherwise transmit LRDM to next hop
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x1 = SE(k, y, x)
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{
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a: "d",
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p: p,
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v: 0,
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x: x1,
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y: y ^ HS(k)
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}
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link immediate dht message (LIDM):
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transfer one or more dht messages directly without a previously made path.
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{
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a: "m",
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m: [many, dht, messages],
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v: 0
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}
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link stateless relay message (LSRM)
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statelessly relay a link message.
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{
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a: "r",
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c: r_counter_uint8,
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d: "<32 bytes rc.K of destination>",
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s: "<32 bytes rc.K of source>",
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v: 0,
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x: "<N bytes encrypted link message>",
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y: "<24 bytes nounce>",
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z: "<64 bytes signature>"
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}
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ONLY exchanged over ethernet, if recieved from an IP link it MUST be discarded.
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relay an encrypted link message from source s to destination d.
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check signature z using public key s and discard if invalid signature.
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if d is equal to ourRC.k then decrypt x via SD(KE(d, s), y, x) and process it as
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a link message. if the inner decrypted link message is a LRCM forward all
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following LRUM, LRDM and LRSM to s via a LSRM. LIDM and LSRM are discarded.
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if d is not equal to ourRC.k then forward it to an ethernet peer that is cloeser
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to d than you are. if you are closer to d than all of your other ethernet peers
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then increment c and send to the ethernet peer with the lowest detected latency
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that isn't the peer that this message was recieved from but ONLY if c is less
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than 128. if c is equal to or greater than 128 then the message is discarded.
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---
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routing layer:
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the routing layer provides inter network communication between the LLARP link
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layer and ip (internet protocol) for exit traffic or ap (anonymous protocol) for
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hidden services. replies to messages are sent back via the path they
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originated from inside a LRDM. all routing messages have an S value which
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provides the sequence number of the message so the messages can be ordered.
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ipv4 addresses are allowed via ipv4 mapped ipv6 addresses, i.e. ::ffff.10.0.0.1
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path confirm message (PCM)
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sent as the first message down a path after it's built to confirm it was built
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always the first message sent
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{
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A: "P",
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L: uint64_milliseconds_path_lifetime,
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S: 0,
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T: uint64_milliseconds_sent_timestamp,
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V: 0
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}
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path latency message (PLM)
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a latency measurement message, reply with a PLM response if we are the far end of a path.
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variant 1, request, generated by the path creator:
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{
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A: "L",
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S: uint64_sequence_number,
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V: 0
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}
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variant 2, response, generated by the endpoint that recieved the request.
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{
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A: "L",
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S: uint64_sequence_number,
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T: uint64_timestamp_sent,
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V: 0
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}
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obtain exit address message (OXAM)
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sent to an exit router to obtain a NAT ip address for ip exit traffic.
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replies are sent down the path that messages originate from.
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{
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A: "X",
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I: "<32 bytes signing public key for future communication>",
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S: uint64_sequence_number,
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T: uint64_transaction_id,
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V: 0,
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X: lifetime_of_address_mapping_in_seconds_uint64,
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Z: "<64 bytes signature using I>"
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}
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grant exit address messsage (GXAM)
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sent in response to an OXAM to grant an ip for exit traffic from an external
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ip address used for exit traffic.
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{
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A: "G",
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E: XR,
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I: "<32 bytes signing public key of requester>",
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S: uint64_sequence_number,
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T: transaction_id_uint64,
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V: 0,
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Z: "<64 bytes signature using exit info's signing key>"
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}
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E contains an exit route that was granted to the requester that can be used with
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IP exit traffic.
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The requester will now have any ip traffic going to address S forwarded to them
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via the path that originally sent the OXAM and any TDFM will is recieved on the
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same path will be forwarded out to the internet, given that they have
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valid signatures and addresses.
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reject exit address message (RXAM)
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sent in response to an OXAM to indicate that exit traffic is not allowed or
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was denied.
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{
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A: "J",
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B: backoff_milliseconds_uint64,
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I: "<32 bytes signing public key of requester>",
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R: "<optional reject metadata>",
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S: uint64_sequence_number,
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T: transaction_id_uint64,
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V: 0,
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Z: "<64 bytes signature signed by exit info's signing key>"
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}
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B is set to a backoff value.
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R contains additional metadata text describing why the exit was rejected.
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transfer data fragment message (TDFM)
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transfer data between paths.
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{
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A: "T",
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P: "<16 bytes path id>",
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S: uint64_sequence_number,
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T: message_transfered_between_paths,
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V: 0
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}
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transfer data to another path with id P on the local router place a random 32 byte and T values
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into y and z values into a LRDM message (respectively) and send it in the
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downstream direction.
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hidden service data (HSD)
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data sent anonymously over the network to a recipiant from a sender.
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sent inside a HSFM encrypted with a shared secret.
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{
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a: protocol_number_uint,
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d: "<N bytes payload>",
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i: Introduction for reply,
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n: uint_message_sequence_number,
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o: N seconds until this converstation plans terminate,
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s: SI of sender,
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t: "<16 bytes converstation tag present only when n is 0>",
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v: 0
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}
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hidden service frame (HSF)
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TODO: document this better
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intro message (variant 1)
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start a new session
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{
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A: "H",
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C: "<1048 bytes ciphertext block>",
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D: "<N bytes encrypted HSD>",
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N: "<32 bytes nonce for key exchange>",
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V: 0,
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Z: "<64 bytes signature of entire message using sender's signing key>"
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}
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alice (A) wants to talk to bob (B) over the network, both have hidden services
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set up and are online on the network.
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A and B are both SI.
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A_sk is alice's private signing key.
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for alice (A) to send the string "beep" to bob (B), alice picks an introduction
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to use on one of her paths (I_A) such that I_A is aligning with one of bobs's
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paths (I_B)
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alice generates:
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T = RAND(16)
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m = {
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a: 0,
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d: "beep",
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i: I_A,
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n: 0,
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s: A,
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t: T,
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v: 0
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}
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X = BE(m)
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C, K = PQKE_A(I_B.k)
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N = RAND(32)
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D = SE(X, K, N)
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M = {
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A: "T",
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P: I_B.P,
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S: uint64_sequence_number,
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T: {
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A: "H",
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C: C,
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D: D,
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N: N,
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V: 0,
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Z: "\x00" * 32
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},
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V: 0
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}
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Z = S(A_sk, BE(M))
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|
alice transmits a TDFM to router with public key I_B.K via her path that ends
|
|
with router with public key I_B.k
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{
|
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A: "T",
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P: I_B.P,
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|
S: uint64_sequence_number,
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|
T: {
|
|
A: "H",
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|
C: C,
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|
D: D,
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N: N,
|
|
V: 0,
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|
Z: Z
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|
},
|
|
V: 0
|
|
}
|
|
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|
the shared secret (S) for further message encryption is:
|
|
|
|
S = HS(K + PKE(A, B, sk, N))
|
|
|
|
given sk is the local secret encryption key used by the current hidden service
|
|
|
|
please note:
|
|
signature verification can only be done after decryption
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|
|
|
TODO: explain bob's side too (it's invsere of alice's process)
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|
|
|
data from a previously made session (variant 2)
|
|
|
|
transfer data on a session previously made
|
|
|
|
{
|
|
A: "H",
|
|
D: "<N bytes encrypted HSD>",
|
|
N: "<32 bytes nonce for symettric cipher>",
|
|
T: "<16 bytes converstation tag>",
|
|
V: 0,
|
|
Z: "<64 bytes signature using sender's signing key>"
|
|
}
|
|
|
|
|
|
transfer ip traffic message (TITM)
|
|
|
|
transfer ip traffic for exit
|
|
|
|
{
|
|
A: "E",
|
|
S: uint64_sequence_number,
|
|
V: 0,
|
|
X: "<N bytes ipv6 packet>",
|
|
Y: "<16 bytes nounce>",
|
|
Z: "<64 bytes signature using previously provided signing key>"
|
|
}
|
|
|
|
X is parsed as an IPv6 packet and the source addresss is extracted.
|
|
Next we find the corrisponding signing key for a previously granted exit address
|
|
and use it to validate the siganture of the entire message. If the signing key
|
|
cannot be found or the signature is invalid this message is dropped, otherwise
|
|
the X value is sent on the appropriate exit network interface.
|
|
|
|
When we recieve an ip packet from the internet to an exit address, we put it
|
|
into a TITM, signed with the exit info's signing key and send it downstream the
|
|
corrisponding path in an LRDM.
|
|
|
|
update exit path message (UXPM)
|
|
|
|
sent from a new path by client to indicate that a previously established exit
|
|
should use the new path that this message came from.
|
|
|
|
{
|
|
A: "U",
|
|
S: uint64_sequence_number,
|
|
T: transaction_id_uint64,
|
|
V: 0,
|
|
Y: "<16 bytes nounce>",
|
|
Z: "<64 bytes signature using previously provided signing key>"
|
|
}
|
|
|
|
T is the transaction ID from the GXAM
|
|
|
|
close exit path message (CXPM)
|
|
|
|
client sends a CXPM when the exit is no longer needed.
|
|
The address used in exit MAY be reused later.
|
|
|
|
{
|
|
A: "C",
|
|
S: uint64_sequence_number,
|
|
T: transaction_id_uint64,
|
|
V: 0,
|
|
Y: "<16 bytes nounce>",
|
|
Z: "<64 bytes signagure using previously provided signing key>"
|
|
}
|
|
|
|
DHT message holder message:
|
|
|
|
wrapper message for sending many dht messages down a path.
|
|
|
|
{
|
|
A: "M",
|
|
M: [many, dht, messages, here],
|
|
S: uint64_sequence_number,
|
|
V: 0
|
|
}
|