README.md

Rendezvous Protocol

Lifecycle Stage	Maturity	Status	Latest Revision
1A	Working Draft	Active	r1, 2019-01-18

Authors: @vyzo

Interest Group: @daviddias, @whyrusleeping, @Stebalien, @jacobheun, @yusefnapora

See the lifecycle document for context about maturity level and spec status.

Overview

The protocol described in this specification is intended to provide a lightweight mechanism for generalized peer discovery. It can be used for bootstrap purposes, real time peer discovery, application specific routing, and so on. Any node implementing the rendezvous protocol can act as a rendezvous point, allowing the discovery of relevant peers in a decentralized fashion.

Use Cases

Depending on the application, the protocol could be used in the following context:

• During bootstrap, a node can use known rendezvous points to discover peers that provide critical services. For instance, rendezvous can be used to discover circuit relays for connectivity restricted nodes.
• During initialization, a node can use rendezvous to discover peers to connect with the rest of the application. For instance, rendezvous can be used to discover pubsub peers within a topic.
• In a real time setting, applications can poll rendezvous points in order to discover new peers in a timely fashion.
• In an application specific routing setting, rendezvous points can be used to progressively discover peers that can answer specific queries or host shards of content.

Replacing ws-star-rendezvous

We intend to replace ws-star-rendezvous with a few rendezvous daemons and a fleet of p2p-circuit relays. Real-time applications will utilize rendezvous both for bootstrap and in a real-time setting. During bootstrap, rendezvous will be used to discover circuit relays that provide connectivity for browser nodes. Subsequently, rendezvous will be utilized throughout the lifetime of the application for real time peer discovery by registering and polling rendezvous points. This allows us to replace a fragile centralized component with a horizontally scalable ensemble of daemons.

Rendezvous and pubsub

Rendezvous can be naturally combined with pubsub for effective real-time discovery. At a basic level, rendezvous can be used to bootstrap pubsub: nodes can utilize rendezvous in order to discover their peers within a topic. Alternatively, pubsub can also be used as a mechanism for building rendezvous services. In this scenerio, a number of rendezvous points can federate using pubsub for internal real-time distribution, while still providing a simple interface to clients.

The Protocol

The rendezvous protocol provides facilities for real-time peer discovery within application specific namespaces. Peers connect to the rendezvous point and register their presence in one or more namespaces. It is not allowed to register arbitrary peers in a namespace; only the peer initiating the registration can register itself.

Peers registered with the rendezvous point can be discovered by other nodes by querying the rendezvous point. The query specifies the namespace for limiting application scope and optionally a maximum number of peers to return. The namespace can be omitted in the query, which asks for all peers registered to the rendezvous point.

The query can also include a cookie, obtained from the response to a previous query, such that only registrations that weren't included in the previous response will be returned. This allows peers to progressively refresh their network view without overhead, which greatly simplifies real time discovery. It also allows for pagination of query responses, so that large numbers of peer registrations can be managed.

Registration Lifetime

Registration lifetime is controlled by an optional TTL parameter in the REGISTER message. If a TTL is specified, then the registration persists until the TTL expires. If no TTL was specified, then a default of 2hrs is implied. There may be a rendezvous point-specific upper bound on TTL, with a minimum such value of 72hrs. If the TTL of a registration is inadmissible, the rendezvous point may reject the registration with an E_INVALID_TTL status.

Peers can refresh their registrations at any time with a new REGISTER message; the TTL of the new message supersedes previous registrations. Peers can also cancel existing registrations at any time with an explicit UNREGISTER message.

The registration response includes the actual TTL of the registration, so that peers know when to refresh.

Interaction

Clients A and B connect to the rendezvous point R and register for namespace my-app with a REGISTER message:

A -> R: REGISTER{my-app, {QmA, AddrA}}
R -> A: {OK}
B -> R: REGISTER{my-app, {QmB, AddrB}}
R -> B: {OK}

Client C connects and registers for namespace another-app:

C -> R: REGISTER{another-app, {QmC, AddrC}}
R -> C: {OK}

Another client D can discover peers in my-app by sending a DISCOVER message; the rendezvous point responds with the list of current peer reigstrations and a cookie.

D -> R: DISCOVER{ns: my-app}
R -> D: {[REGISTER{my-app, {QmA, Addr}}
          REGISTER{my-app, {QmB, Addr}}],
         c1}

If D wants to discover all peers registered with R, then it can omit the namespace in the query:

D -> R: DISCOVER{}
R -> D: {[REGISTER{my-app, {QmA, Addr}}
          REGISTER{my-app, {QmB, Addr}}
          REGISTER{another-app, {QmC, AddrC}}],
         c2}

If D wants to progressively poll for real time discovery, it can use the cookie obtained from a previous response in order to only ask for new registrations.

So here we consider a new client E registering after the first query, and a subsequent query that discovers just that peer by including the cookie:

E -> R: REGISTER{my-app, {QmE, AddrE}}
R -> E: {OK}
D -> R: DISCOVER{ns: my-app, cookie: c1}
R -> D: {[REGISTER{my-app, {QmE, AddrE}}],
         c3}

Proof of Work

The protocol as described so far is susceptible to spam attacks from adversarial actors who generate a large number of peer identities and register under a namespace of interest (eg: the relay namespace). This can be mitigated by requiring a Proof of Work scheme for client registrations.

This is TBD before finalizing the spec.

Protobuf

message Message {
  enum MessageType {
    REGISTER = 0;
    REGISTER_RESPONSE = 1;
    UNREGISTER = 2;
    DISCOVER = 3;
    DISCOVER_RESPONSE = 4;
  }

  enum ResponseStatus {
    OK                  = 0;
    E_INVALID_NAMESPACE = 100;
    E_INVALID_PEER_INFO = 101;
    E_INVALID_TTL       = 102;
    E_INVALID_COOKIE    = 103;
    E_NOT_AUTHORIZED    = 200;
    E_INTERNAL_ERROR    = 300;
    E_UNAVAILABLE       = 400;
  }

  message PeerInfo {
    optional bytes id = 1;
    repeated bytes addrs = 2;
  }

  message Register {
    optional string ns = 1;
    optional PeerInfo peer = 2;
    optional int64 ttl = 3; // in seconds
  }

  message RegisterResponse {
    optional ResponseStatus status = 1;
    optional string statusText = 2;
    optional int64 ttl = 3; // in seconds
  }

  message Unregister {
    optional string ns = 1;
    optional bytes id = 2;
  }

  message Discover {
    optional string ns = 1;
    optional int64 limit = 2;
    optional bytes cookie = 3;
  }

  message DiscoverResponse {
    repeated Register registrations = 1;
    optional bytes cookie = 2;
    optional ResponseStatus status = 3;
    optional string statusText = 4;
  }

  optional MessageType type = 1;
  optional Register register = 2;
  optional RegisterResponse registerResponse = 3;
  optional Unregister unregister = 4;
  optional Discover discover = 5;
  optional DiscoverResponse discoverResponse = 6;
}