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-rw-r--r--docs/olm.rst127
1 files changed, 120 insertions, 7 deletions
diff --git a/docs/olm.rst b/docs/olm.rst
index 07836f6..db32cdb 100644
--- a/docs/olm.rst
+++ b/docs/olm.rst
@@ -19,24 +19,137 @@ The setup takes four Curve25519 inputs: Identity keys for Alice and Bob,
:math:`E_A` and :math:`E_B`. A shared secret, :math:`S`, is generated using
Triple Diffie-Hellman. The initial 256 bit root key, :math:`R_0`, and 256 bit
chain key, :math:`C_{0,0}`, are derived from the shared secret using an
-HMAC-based Key Derivation Function (HKDF).
+HMAC-based Key Derivation Function (HKDF) with default salt.
.. math::
\begin{align}
S&=ECDH\left(I_A,\,E_B\right)\;\parallel\;ECDH\left(E_A,\,I_B\right)\;
\parallel\;ECDH\left(E_A,\,E_B\right)\\
- R_0\;\parallel\;C_{0,0}&=HKDF(S,\,\text{"OLM\_ROOT"})
+ R_0\;\parallel\;C_{0,0}&=HKDF\left(S,\,\text{"OLM\_ROOT"}\right)
\end{align}
Advancing the root key
~~~~~~~~~~~~~~~~~~~~~~
Advancing a root key takes the previous root key, :math:`R_{i-1}`, and two
-Curve25519 inputs: The previous ratchet key, :math:`T_{i-1}`, and the current
-ratchet key :math:`T_{i}`. The even ratchet keys are generated by Alice.
-The odd ratchet keys are generated by Bob. A shared secret, `S` is generated
-using Diffie-Hellman on the ratchet keys. The next root key, :math:`R_o`, and
+Curve25519 inputs: the previous ratchet key, :math:`T_{i-1}`, and the current
+ratchet key :math:`T_i`. The even ratchet keys are generated by Alice.
+The odd ratchet keys are generated by Bob. A shared secret is generated
+using Diffie-Hellman on the ratchet keys. The next root key, :math:`R_i`, and
chain key, :math:`C_{i,0}`, are derived from the shared secret using an
-HMAC-based Key Derivation Function (HKDF).
+HMAC-based Key Derivation Function (HKDF) using :math:`R_{i-1}` as the salt.
+.. math::
+ \begin{align}
+ R_i\;\parallel\;C_{i,0}&=HKDF\left(
+ ECDH\left(T_{i-1},\,T_i\right),\,
+ R_{i-1},\,
+ \text{"OLM\_RATCHET"}
+ \right)
+ \end{align}
+
+
+Advancing the chain key
+~~~~~~~~~~~~~~~~~~~~~~~
+
+Advancing a root key takes the previous chain key, :math:`C_{i,j-i}`. The next
+chain key, :math:`C_{i,j}`, is the HMAC of ``"\x02"`` using the previous chain
+key as the key.
+
+.. math::
+ \begin{align}
+ C_{i,j}&=HMAC\left(C_{i,j-1},\,\text{"\textbackslash x02"}\right)
+ \end{align}
+
+Creating a message key
+~~~~~~~~~~~~~~~~~~~~~~
+
+Creating a message key takes the current chain key, :math:`C_{i,j}`. The
+message key, :math:`M_{i,j}`, is the HMAC of ``"\x01"`` using the current
+chain key as the key. The message keys where :math:`i` is even are used by
+Alice to encrypt messages. The message keys where :math:`i` is odd are used
+by Bob to encrypt messages.
+
+.. math::
+ \begin{align}
+ M_{i,j}&=HMAC\left(C_{i,j},\,\text{"\textbackslash x01"}\right)
+ \end{align}
+
+
+The Olm Protocol
+----------------
+
+Creating an outbound session
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Bob publishes his identity key, :math:`I_B`, and some single-use one-time
+keys :math:`E_B`.
+
+Alice downloads Bob's identity key, :math:`I_B`, and a one-time key,
+:math:`E_B`. Alice takes her identity key, :math:`I_A`, and generates a new
+single-use key, :math:`E_A`. Alice computes a root key, :math:`R_0`, and a
+chain key :math:`C_{0,0}`. Alice generates a new ratchet key :math:`T_0`.
+
+Sending the first pre-key messages
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Alice computes a message key, :math:`M_{0,j}`, using the current chain key,
+:math:`C_{0,j}`. Alice replaces the current chain key with :math:`C_{0,j+1}`.
+Alice encrypts her plain-text with the message key, :math:`M_{0,j}`, using an
+authenticated encryption scheme to get a cipher-text, :math:`X_{0,j}`. Alice
+sends her identity key, :math:`I_A`, her single-use key, :math:`E_A`, Bob's
+single-use key, :math:`E_B`, the current chain index, :math:`j`, her ratchet
+key, :math:`T_0`, and the cipher-text, :math:`X_{0,j}`, to Bob.
+
+Alice will continue to send pre-key messages until she receives a message from
+Bob.
+
+Creating an inbound session from a pre-key message
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+
+Bob receives a pre-key message with Alice's identity key, :math:`I_A`,
+Alice's single-use key, :math:`E_A`, the public part of his single-use key,
+:math:`E_B`, the current chain index, :math:`j`, Alice's ratchet key,
+:math:`T_0`, and the cipher-text, :math:`X_{0,j}`. Bob looks up the private
+part of the single-use key, :math:`E_B`. Bob computes the root key :math:`R_0`,
+and the chain key :math:`C_{0,0}`. Bob then advances the chain key to compute
+the chain key used by the message, :math:`C_{0,j}`. Bob then creates the
+message key, :math:`M_{0,j}`, and attempts to decrypt the ciphertext,
+:math:`X_{0,j}`. If the cipher-text's authentication is correct then Bob can
+discard private part of his single-use one-time key, :math:`E_B`.
+
+Sending messages
+~~~~~~~~~~~~~~~~
+
+To send a message the user checks if they have a sender chain key,
+:math:`C_{i,j}`. Alice use chain keys where :math:`i` is even. Bob uses chain
+keys where :math:`i` is odd. If the chain key doesn't exist then a new ratchet
+key :math:`T_i` is generated and a the chain key, :math:`C_{i,0}`, is computed
+using :math:`R_{i-1}`, :math:`T_{i-1}` and :math:`T_i`. A message key,
+:math:`M_{i,j}` is computed from the current chain key, :math:`C_{i,j}`, and
+the chain key is replaced with the next chain key, :math:`C_{i,j+1}`. The
+plain-text is encrypted with :math:`M_{i,j}`, using an authenticated encryption
+scheme to get a cipher-text, :math:`X_{i,j}`. Then user sends the current
+chain index, :math:`j`, the ratchet key, :math:`T_i`, and the cipher-text,
+:math:`X_{i,j}`, to the other user.
+
+Receiving messages
+~~~~~~~~~~~~~~~~~~
+
+The user receives a message with the current chain index, :math:`j`, the
+ratchet key, :math:`T_i`, and the cipher-text, :math:`X_{i,j}`, from the
+other user. The user checks if they have a receiver chain with the correct
+:math:`i` by comparing the ratchet key, :math:`T_i`. If the chain doesn't exist
+then they compute a new receiver chain, :math:`C_{i,0}`, using :math:`R_{i-1}`,
+:math:`T_{i-1}` and :math:`T_i`. If the :math:`j` of the message is less than
+the current chain index on the receiver then the message may only be decrypted
+if the receiver has stored a copy of the message key :math:`M_{i,j}`. Otherwise
+the receiver computes the chain key, :math:`C_{i,j}`. The receiver computes the
+message key, :math:`M_{i,j}`, from the chain key and attempts to decrypt the
+cipher-text, :math:`X_{i,j}`.
+If the decryption succeeds the reciever updates the chain key for :math:`T_i`
+with :math:`C_{i,j+1}` and stores the message keys that were skipped in the
+process so that they can decode out of order messages. If the receiver created
+a new receiver chain then they discard their current sender chain so that
+they will create a new chain when they next send a message.