326 lines
13 KiB
Markdown
326 lines
13 KiB
Markdown
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# Megolm group ratchet
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An AES-based cryptographic ratchet intended for group communications.
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## Background
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The Megolm ratchet is intended for encrypted messaging applications where there
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may be a large number of recipients of each message, thus precluding the use of
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peer-to-peer encryption systems such as [Olm][].
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It also allows a recipient to decrypt received messages multiple times. For
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instance, in client/server applications, a copy of the ciphertext can be stored
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on the (untrusted) server, while the client need only store the session keys.
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## Overview
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Each participant in a conversation uses their own outbound session for
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encrypting messages. A session consists of a ratchet and an [Ed25519][] keypair.
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Secrecy is provided by the ratchet, which can be wound forwards but not
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backwards, and is used to derive a distinct message key for each message.
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Authenticity is provided via Ed25519 signatures.
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The value of the ratchet, and the public part of the Ed25519 key, are shared
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with other participants in the conversation via secure peer-to-peer
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channels. Provided that peer-to-peer channel provides authenticity of the
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messages to the participants and deniability of the messages to third parties,
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the Megolm session will inherit those properties.
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## The Megolm ratchet algorithm
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The Megolm ratchet $`R_i`$ consists of four parts, $`R_{i,j}`$ for
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$`j \in {0,1,2,3}`$. The length of each part depends on the hash function
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in use (256 bits for this version of Megolm).
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The ratchet is initialised with cryptographically-secure random data, and
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advanced as follows:
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```math
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\begin{aligned}
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R_{i,0} &=
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\begin{cases}
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H_0\left(R_{2^24(n-1),0}\right) &\text{if }\exists n | i = 2^24n\\
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R_{i-1,0} &\text{otherwise}
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\end{cases}\\
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R_{i,1} &=
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\begin{cases}
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H_1\left(R_{2^24(n-1),0}\right) &\text{if }\exists n | i = 2^24n\\
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H_1\left(R_{2^16(m-1),1}\right) &\text{if }\exists m | i = 2^16m\\
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R_{i-1,1} &\text{otherwise}
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\end{cases}\\
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R_{i,2} &=
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\begin{cases}
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H_2\left(R_{2^24(n-1),0}\right) &\text{if }\exists n | i = 2^24n\\
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H_2\left(R_{2^16(m-1),1}\right) &\text{if }\exists m | i = 2^16m\\
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H_2\left(R_{2^8(p-1),2}\right) &\text{if }\exists p | i = 2^8p\\
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R_{i-1,2} &\text{otherwise}
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\end{cases}\\
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R_{i,3} &=
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\begin{cases}
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H_3\left(R_{2^24(n-1),0}\right) &\text{if }\exists n | i = 2^24n\\
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H_3\left(R_{2^16(m-1),1}\right) &\text{if }\exists m | i = 2^16m\\
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H_3\left(R_{2^8(p-1),2}\right) &\text{if }\exists p | i = 2^8p\\
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H_3\left(R_{i-1,3}\right) &\text{otherwise}
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\end{cases}
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\end{aligned}
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```
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where $`H_0`$, $`H_1`$, $`H_2`$, and $`H_3`$ are different hash
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functions. In summary: every $`2^8`$ iterations, $`R_{i,3}`$ is
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reseeded from $`R_{i,2}`$. Every $`2^16`$ iterations, $`R_{i,2}`$
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and $`R_{i,3}`$ are reseeded from $`R_{i,1}`$. Every $`2^24`$
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iterations, $`R_{i,1}`$, $`R_{i,2}`$ and $`R_{i,3}`$ are reseeded
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from $`R_{i,0}`$.
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The complete ratchet value, $`R_{i}`$, is hashed to generate the keys used
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to encrypt each message. This scheme allows the ratchet to be advanced an
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arbitrary amount forwards while needing at most 1023 hash computations. A
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client can decrypt chat history onwards from the earliest value of the ratchet
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it is aware of, but cannot decrypt history from before that point without
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reversing the hash function.
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This allows a participant to share its ability to decrypt chat history with
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another from a point in the conversation onwards by giving a copy of the
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ratchet at that point in the conversation.
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## The Megolm protocol
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### Session setup
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Each participant in a conversation generates their own Megolm session. A
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session consists of three parts:
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* a 32 bit counter, $`i`$.
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* an [Ed25519][] keypair, $`K`$.
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* a ratchet, $`R_i`$, which consists of four 256-bit values,
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$`R_{i,j}`$ for $`j \in {0,1,2,3}`$.
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The counter $`i`$ is initialised to $`0`$. A new Ed25519 keypair is
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generated for $`K`$. The ratchet is simply initialised with 1024 bits of
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cryptographically-secure random data.
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A single participant may use multiple sessions over the lifetime of a
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conversation. The public part of $`K`$ is used as an identifier to
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discriminate between sessions.
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### Sharing session data
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To allow other participants in the conversation to decrypt messages, the
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session data is formatted as described in [Session-sharing format](#Session-sharing-format). It is then
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shared with other participants in the conversation via a secure peer-to-peer
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channel (such as that provided by [Olm][]).
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When the session data is received from other participants, the recipient first
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checks that the signature matches the public key. They then store their own
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copy of the counter, ratchet, and public key.
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### Message encryption
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This version of Megolm uses AES-256_ in CBC_ mode with [PKCS#7][] padding and
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HMAC-SHA-256_ (truncated to 64 bits). The 256 bit AES key, 256 bit HMAC key,
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and 128 bit AES IV are derived from the megolm ratchet $`R_i`$:
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```math
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\begin{aligned}
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AES\_KEY_{i}\;\parallel\;HMAC\_KEY_{i}\;\parallel\;AES\_IV_{i}
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&= HKDF\left(0,\,R_{i},\text{"MEGOLM\_KEYS"},\,80\right) \\
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\end{aligned}
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```
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where $`\parallel`$ represents string splitting, and
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$`HKDF\left(salt,\,IKM,\,info,\,L\right)`$ refers to the [HMAC-based key
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derivation function][] using using [SHA-256][] as the hash function
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([HKDF-SHA-256][]) with a salt value of $`salt`$, input key material of
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$`IKM`$, context string $`info`$, and output keying material length of
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$`L`$ bytes.
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The plain-text is encrypted with AES-256, using the key $`AES\_KEY_{i}`$
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and the IV $`AES\_IV_{i}`$ to give the cipher-text, $`X_{i}`$.
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The ratchet index $`i`$, and the cipher-text $`X_{i}`$, are then packed
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into a message as described in [Message format](#message-format). Then the entire message
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(including the version bytes and all payload bytes) are passed through
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HMAC-SHA-256. The first 8 bytes of the MAC are appended to the message.
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Finally, the authenticated message is signed using the Ed25519 keypair; the 64
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byte signature is appended to the message.
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The complete signed message, together with the public part of $`K`$ (acting
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as a session identifier), can then be sent over an insecure channel. The
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message can then be authenticated and decrypted only by recipients who have
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received the session data.
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### Advancing the ratchet
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After each message is encrypted, the ratchet is advanced. This is done as
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described in [The Megolm ratchet algorithm](#the-megolm-ratchet-algorithm), using the following definitions:
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```math
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\begin{aligned}
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H_0(A) &\equiv HMAC(A,\text{"\x00"}) \\
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H_1(A) &\equiv HMAC(A,\text{"\x01"}) \\
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H_2(A) &\equiv HMAC(A,\text{"\x02"}) \\
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H_3(A) &\equiv HMAC(A,\text{"\x03"}) \\
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\end{aligned}
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```
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where $`HMAC(A, T)`$ is the HMAC-SHA-256 of ``T``, using ``A`` as the
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key.
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For outbound sessions, the updated ratchet and counter are stored in the
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session.
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In order to maintain the ability to decrypt conversation history, inbound
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sessions should store a copy of their earliest known ratchet value (unless they
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explicitly want to drop the ability to decrypt that history - see [Partial
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Forward Secrecy](#partial-forward-secrecy)). They may also choose to cache calculated ratchet values,
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but the decision of which ratchet states to cache is left to the application.
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## Data exchange formats
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### Session-sharing format
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The Megolm key-sharing format is as follows:
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```
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+---+----+--------+--------+--------+--------+------+-----------+
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| V | i | R(i,0) | R(i,1) | R(i,2) | R(i,3) | Kpub | Signature |
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+---+----+--------+--------+--------+--------+------+-----------+
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0 1 5 37 69 101 133 165 229 bytes
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```
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The version byte, ``V``, is ``"\x02"``.
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This is followed by the ratchet index, $`i`$, which is encoded as a
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big-endian 32-bit integer; the ratchet values $`R_{i,j}`$; and the public
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part of the Ed25519 keypair $`K`$.
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The data is then signed using the Ed25519 keypair, and the 64-byte signature is
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appended.
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### Message format
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Megolm messages consist of a one byte version, followed by a variable length
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payload, a fixed length message authentication code, and a fixed length
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signature.
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```
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+---+------------------------------------+-----------+------------------+
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| V | Payload Bytes | MAC Bytes | Signature Bytes |
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+---+------------------------------------+-----------+------------------+
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0 1 N N+8 N+72 bytes
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```
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The version byte, ``V``, is ``"\x03"``.
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The payload uses a format based on the [Protocol Buffers encoding][]. It
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consists of the following key-value pairs:
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**Name**|**Tag**|**Type**|**Meaning**
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:-----:|:-----:|:-----:|:-----:
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Message-Index|0x08|Integer|The index of the ratchet, i
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Cipher-Text|0x12|String|The cipher-text, Xi, of the message
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Within the payload, integers are encoded using a variable length encoding. Each
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integer is encoded as a sequence of bytes with the high bit set followed by a
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byte with the high bit clear. The seven low bits of each byte store the bits of
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the integer. The least significant bits are stored in the first byte.
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Strings are encoded as a variable-length integer followed by the string itself.
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Each key-value pair is encoded as a variable-length integer giving the tag,
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followed by a string or variable-length integer giving the value.
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The payload is followed by the MAC. The length of the MAC is determined by the
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authenticated encryption algorithm being used (8 bytes in this version of the
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protocol). The MAC protects all of the bytes preceding the MAC.
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The length of the signature is determined by the signing algorithm being used
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(64 bytes in this version of the protocol). The signature covers all of the
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bytes preceding the signature.
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## Limitations
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### Message Replays
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A message can be decrypted successfully multiple times. This means that an
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attacker can re-send a copy of an old message, and the recipient will treat it
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as a new message.
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To mitigate this it is recommended that applications track the ratchet indices
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they have received and that they reject messages with a ratchet index that
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they have already decrypted.
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### Lack of Transcript Consistency
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In a group conversation, there is no guarantee that all recipients have
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received the same messages. For example, if Alice is in a conversation with Bob
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and Charlie, she could send different messages to Bob and Charlie, or could
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send some messages to Bob but not Charlie, or vice versa.
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Solving this is, in general, a hard problem, particularly in a protocol which
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does not guarantee in-order message delivery. For now it remains the subject of
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future research.
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### Lack of Backward Secrecy
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Once the key to a Megolm session is compromised, the attacker can decrypt any
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future messages sent via that session.
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In order to mitigate this, the application should ensure that Megolm sessions
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are not used indefinitely. Instead it should periodically start a new session,
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with new keys shared over a secure channel.
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<!-- TODO: Can we recommend sensible lifetimes for Megolm sessions? Probably
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depends how paranoid we're feeling, but some guidelines might be useful. -->
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### Partial Forward Secrecy
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Each recipient maintains a record of the ratchet value which allows them to
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decrypt any messages sent in the session after the corresponding point in the
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conversation. If this value is compromised, an attacker can similarly decrypt
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those past messages.
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To mitigate this issue, the application should offer the user the option to
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discard historical conversations, by winding forward any stored ratchet values,
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or discarding sessions altogether.
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### Dependency on secure channel for key exchange
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The design of the Megolm ratchet relies on the availability of a secure
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peer-to-peer channel for the exchange of session keys. Any vulnerabilities in
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the underlying channel are likely to be amplified when applied to Megolm
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session setup.
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For example, if the peer-to-peer channel is vulnerable to an unknown key-share
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attack, the entire Megolm session become similarly vulnerable. For example:
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Alice starts a group chat with Eve, and shares the session keys with Eve. Eve
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uses the unknown key-share attack to forward the session keys to Bob, who
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believes Alice is starting the session with him. Eve then forwards messages
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from the Megolm session to Bob, who again believes they are coming from
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Alice. Provided the peer-to-peer channel is not vulnerable to this attack, Bob
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will realise that the key-sharing message was forwarded by Eve, and can treat
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the Megolm session as a forgery.
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A second example: if the peer-to-peer channel is vulnerable to a replay
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attack, this can be extended to entire Megolm sessions.
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## License
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The Megolm specification (this document) is licensed under the Apache License,
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Version 2.0 http://www.apache.org/licenses/LICENSE-2.0.
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[Ed25519]: http://ed25519.cr.yp.to/
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[HMAC-based key derivation function]: https://tools.ietf.org/html/rfc5869
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[HKDF-SHA-256]: https://tools.ietf.org/html/rfc5869
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[HMAC-SHA-256]: https://tools.ietf.org/html/rfc2104
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[SHA-256]: https://tools.ietf.org/html/rfc6234
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[AES-256]: http://csrc.nist.gov/publications/fips/fips197/fips-197.pdf
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[CBC]: http://csrc.nist.gov/publications/nistpubs/800-38a/sp800-38a.pdf
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[PKCS#7]: https://tools.ietf.org/html/rfc2315
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[Olm]: https://gitlab.matrix.org/matrix-org/olm/blob/master/docs/olm.md
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[Protocol Buffers encoding]: https://developers.google.com/protocol-buffers/docs/encoding
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