7.2 KiB
slug | title | name | status | tags | editor | contributors |
---|---|---|---|---|---|---|
31 | 31/WAKU2-ENR | Waku v2 usage of ENR | raw | waku-core-protocol | Franck Royer <franck@status.im> |
Abstract
This RFC describes the usage of the ENR (Ethereum Node Records) format for 10/WAKU2 purposes. The ENR format is defined in EIP-778 [3].
This RFC is an extension of EIP-778, ENR used in Waku v2 MUST adhere to both EIP-778 and 31/WAKU2-ENR.
Motivation
EIP-1459 with the usage of ENR has been implemented [1] [2] as a discovery protocol for Waku v2.
EIP-778 specifies a number of pre-defined keys. However, the usage of these keys alone does not allow for certain transport capabilities to be encoded, such as Websocket. Currently, Waku v2 nodes running in a Browser only support websocket transport protocol. Hence, new ENR keys need to be defined to allow for the encoding of transport protocol other than raw TCP.
Usage of Multiaddr Format Rationale
One solution would be to define new keys such as ws
to encode the websocket port of a node.
However, we expect new transport protocols to be added overtime such as quic.
Hence, this would only provide a short term solution until another RFC would need to be added.
Moreover, secure websocket involves SSL certificates. SSL certificates are only valid for a given domain and ip, so an ENR containing the following information:
- secure websocket port
- ipv4 fqdn
- ipv4 address
- ipv6 address
Would carry some ambiguity: Is the certificate securing the websocket port valid for the ipv4 fqdn? the ipv4 address? the ipv6 address?
The 10/WAKU2 protocol family is built on the libp2p protocol stack. Hence, it uses multiaddr to format network addresses.
Directly storing one or several multiaddresses in the ENR would fix the issues listed above:
- multiaddr is self-describing and support addresses for any network protocol: No new RFC would be needed to support encoding other transport protocols in an ENR.
- multiaddr contains both the host and port information, allowing the ambiguity previously described to be resolved.
multiaddrs
ENR key
We define a multiaddrs
key.
- The value MUST be a list of binary encoded multiaddr prefixed by their size.
- The size of the multiaddr MUST be encoded in a Big Endian unsigned 16-bit integer.
- The size of the multiaddr MUST be encoded in 2 bytes.
- The
secp256k1
value MUST be present on the record;secp256k1
is defined in EIP-778 and contains the compressed secp256k1 public key. - The node's peer id SHOULD be deduced from the
secp256k1
value. - The multiaddresses SHOULD NOT contain a peer id.
- For raw TCP & UDP connections details, EIP-778 pre-defined keys SHOULD be used;
The keys
tcp
,udp
,ip
(andtcp6
,udp6
,ip6
for IPv6) are enough to convey all necessary information; - To save space,
multiaddrs
key SHOULD only be used for connection details that cannot be represented using the EIP-778 pre-defined keys. - The 300 bytes size limit as defined by EIP-778 still applies; In practice, it is possible to encode 3 multiaddresses in ENR, more or less could be encoded depending on the size of each multiaddress.
Usage
Many connection types
Alice is a node operator, she runs a node that supports inbound connection for the following protocols:
- TCP 10101 on
1.2.3.4
- UDP 20202 on
1.2.3.4
- TCP 30303 on
1234:5600:101:1::142
- UDP 40404 on
1234:5600:101:1::142
- Secure Websocket on
wss://example.com:443/
- QUIC on
quic://quic.example.com:443/
Alice SHOULD structure the ENR for her node as follows:
key | value |
---|---|
tcp |
10101 |
udp |
20202 |
tcp6 |
30303 |
udp6 |
40404 |
ip |
1.2.3.4 |
ip6 |
1234:5600:101:1::142 |
secp256k1 |
Alice's compressed secp256k1 public key, 33 bytes |
multiaddrs |
len1 | /dns4/example.com/tcp/443/wss | len2 | /dns4/quic.examle.com/tcp/443/quic |
Where:
|
is the concatenation operator,len1
is the length of/dns4/example.com/tcp/443/wss
byte representation,len2
is the length of/dns4/quic.examle.com/tcp/443/quic
byte representation.
Raw TCP only
Bob is a node operator, he runs a node that supports inbound connection for the following protocols:
- TCP 10101 on
1.2.3.4
Bob SHOULD structure the ENR for her node as follows:
key | value |
---|---|
tcp |
10101 |
ip |
1.2.3.4 |
secp256k1 |
Bob's compressed secp256k1 public key, 33 bytes |
Indeed, as Bob's node's connection details can be represented with EIP-778's pre-defined keys only
then it is not needed to use the multiaddrs
key.
Limitations
Supported key type is secp256k1
only.
In the future, an extension of this RFC could be made to support other elliptic curve cryptography such as ed25519
.
waku2
ENR key
We define a waku2
field key:
- The value MUST be an 8-bit flag field,
where bits set to
1
indicatetrue
and bits set to0
indicatefalse
for the relevant flags. - The flag values already defined are set out below,
with
bit 7
the most significant bit andbit 0
the least significant bit.
bit 7 | bit 6 | bit 5 | bit 4 | bit 3 | bit 2 | bit 1 | bit 0 |
---|---|---|---|---|---|---|---|
undef |
undef |
undef |
undef |
lightpush |
filter |
store |
relay |
- In the scheme above, the flags
lightpush
,filter
,store
andrelay
correlates with support for protocols with the same name. If a protocol is not supported, the corresponding field MUST be set tofalse
. Indicating positive support for any specific protocol is OPTIONAL, though it MAY be required by the relevant application or discovery process. - Flags marked as
undef
is not yet defined. These SHOULD be set tofalse
by default.
Usage
- A Waku v2 node MAY choose to populate the
waku2
field for enhanced discovery capabilities, such as indicating supported protocols. Such a node MAY indicate support for any specific protocol by setting the corresponding flag totrue
. - Waku v2 nodes that want to participate in Node Discovery Protocol v5 [4], however,
MUST implement the
waku2
key with at least one flag set totrue
. - Waku v2 nodes that discovered other participants using Discovery v5,
MUST filter out participant records that do not implement this field or do not have at least one flag set to
true
. - In addition, such nodes MAY choose to filter participants on specific flags (such as supported protocols),
or further interpret the
waku2
field as required by the application.
Copyright
Copyright and related rights waived via CC0.