7.4 KiB
slug | title | name | status | editor | contributors |
---|---|---|---|---|---|
26 | 26/WAKU2-PAYLOAD | Waku Message Payload Encryption | draft | Oskar Thoren <oskarth@titanproxy.com> |
This specification describes how Waku provides confidentiality, authenticity, and integrity, as well as some form of unlinkability. Specifically, it describes how encryption, decryption and signing works in 6/WAKU1 and in 10/WAKU2 spec with 14/WAKU-MESSAGE version 1.
This specification effectively replaces 7/WAKU-DATA as well as 6/WAKU1 Payload encryption but written in a way that is agnostic and self-contained for Waku v1 and Waku v2.
Large sections of the specification originate from EIP-627: Whisper spec as well from RLPx Transport Protocol spec (ECIES encryption) with some modifications.
Design requirements
- Confidentiality: The adversary should not be able to learn what data is being sent from one Waku node to one or several other Waku nodes.
- Authenticity: The adversary should not be able to cause Waku endpoint to accept data from any third party as though it came from the other endpoint.
- Integrity: The adversary should not be able to cause a Waku endpoint to accept data that has been tampered with.
Notable, forward secrecy is not provided for at this layer. If this property is desired, a more fully featured secure communication protocol can be used on top, such as Status 5/SECURE-TRANSPORT.
It also provides some form of unlinkability since:
- only participants who are able to decrypt a message can see its signature
- payload are padded to a fixed length
Cryptographic primitives
- AES-256-GCM (for symmetric encryption)
- ECIES
- ECDSA
- KECCAK-256
ECIES is using the following cryptosystem:
- Curve: secp256k1
- KDF: NIST SP 800-56 Concatenation Key Derivation Function, with SHA-256 option
- MAC: HMAC with SHA-256
- AES: AES-128-CTR
Specification
For 6/WAKU1,
the data
field is used in the waku envelope
,
and the field MAY contain the encrypted payload.
For 10/WAKU2 spec,
the payload
field is used in WakuMessage
and
MAY contain the encrypted payload.
The fields that are concatenated and
encrypted as part of the data
(Waku v1) / payload
(Waku v2) field are:
- flags
- payload-length
- payload
- padding
- signature
ABNF
Using Augmented Backus-Naur form (ABNF) we have the following format:
; 1 byte; first two bits contain the size of payload-length field,
; third bit indicates whether the signature is present.
flags = 1OCTET
; contains the size of payload.
payload-length = 4*OCTET
; byte array of arbitrary size (may be zero).
payload = *OCTET
; byte array of arbitrary size (may be zero).
padding = *OCTET
; 65 bytes, if present.
signature = 65OCTET
data = flags payload-length payload padding [signature]
; This field is called payload in Waku v2
payload = data
Signature
Those unable to decrypt the payload/data are also unable to access the signature.
The signature, if provided,
is the ECDSA signature of the Keccak-256 hash of the unencrypted data
using the secret key of the originator identity.
The signature is serialized as the concatenation of the r
, s
and v
parameters
of the SECP-256k1 ECDSA signature, in that order.
r
and s
MUST be big-endian encoded, fixed-width 256-bit unsigned.
v
MUST be an 8-bit big-endian encoded,
non-normalized and should be either 27 or 28.
See Ethereum "Yellow paper": Appendix F Signing transactions for more information on signature generation, parameters and public key recovery.
Encryption
Symmetric
Symmetric encryption uses AES-256-GCM for
authenticated encryption.
The output of encryption is of the form (ciphertext
, tag
, iv
)
where ciphertext
is the encrypted message,
tag
is a 16 byte message authentication tag and
iv
is a 12 byte initialization vector (nonce).
The message authentication tag
and
initialization vector iv
field MUST be appended to the resulting ciphertext
,
in that order.
Note that previous specifications and
some implementations might refer to iv
as nonce
or salt
.
Asymmetric
Asymmetric encryption uses the standard Elliptic Curve Integrated Encryption Scheme (ECIES) with SECP-256k1 public key.
ECIES
This section originates from the RLPx Transport Protocol spec spec with minor modifications.
The cryptosystem used is:
- The elliptic curve secp256k1 with generator
G
. KDF(k, len)
: the NIST SP 800-56 Concatenation Key Derivation Function.MAC(k, m)
: HMAC using the SHA-256 hash function.AES(k, iv, m)
: the AES-128 encryption function in CTR mode.
Special notation used: X || Y
denotes concatenation of X
and Y
.
Alice wants to send an encrypted message that can be decrypted by
Bob's static private key kB
.
Alice knows about Bobs static public key KB
.
To encrypt the message m
, Alice generates a random number r
and
corresponding elliptic curve public key R = r * G
and
computes the shared secret S = Px
where (Px, Py) = r * KB
.
She derives key material for encryption and
authentication as kE || kM = KDF(S, 32)
as well as a random initialization vector iv
.
Alice sends the encrypted message R || iv || c || d
where c = AES(kE, iv , m)
and d = MAC(sha256(kM), iv || c)
to Bob.
For Bob to decrypt the message R || iv || c || d
,
he derives the shared secret S = Px
where (Px, Py) = kB * R
as well as the encryption and authentication keys kE || kM = KDF(S, 32)
.
Bob verifies the authenticity of the message
by checking whether d == MAC(sha256(kM), iv || c)
then obtains the plaintext as m = AES(kE, iv || c)
.
Padding
The padding field is used to align data size, since data size alone might reveal important metainformation. Padding can be arbitrary size. However, it is recommended that the size of Data Field (excluding the IV and tag) before encryption (i.e. plain text) SHOULD be a multiple of 256 bytes.
Decoding a message
In order to decode a message, a node SHOULD try to apply both symmetric and asymmetric decryption operations. This is because the type of encryption is not included in the message.
Copyright
Copyright and related rights waived via CC0.