1521 lines
88 KiB
Markdown
1521 lines
88 KiB
Markdown
# Ethereum 2.0 networking specification
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This document contains the networking specification for Ethereum 2.0 clients.
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It consists of four main sections:
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1. A specification of the network fundamentals.
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2. A specification of the three network interaction *domains* of Eth2: (a) the gossip domain, (b) the discovery domain, and (c) the Req/Resp domain.
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3. The rationale and further explanation for the design choices made in the previous two sections.
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4. An analysis of the maturity/state of the libp2p features required by this spec across the languages in which Eth2 clients are being developed.
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## Table of contents
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<!-- TOC -->
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<!-- START doctoc generated TOC please keep comment here to allow auto update -->
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<!-- DON'T EDIT THIS SECTION, INSTEAD RE-RUN doctoc TO UPDATE -->
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- [Network fundamentals](#network-fundamentals)
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- [Transport](#transport)
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- [Encryption and identification](#encryption-and-identification)
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- [Protocol Negotiation](#protocol-negotiation)
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- [Multiplexing](#multiplexing)
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- [Eth2 network interaction domains](#eth2-network-interaction-domains)
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- [Configuration](#configuration)
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- [MetaData](#metadata)
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- [The gossip domain: gossipsub](#the-gossip-domain-gossipsub)
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- [Topics and messages](#topics-and-messages)
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- [Global topics](#global-topics)
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- [`beacon_block`](#beacon_block)
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- [`beacon_aggregate_and_proof`](#beacon_aggregate_and_proof)
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- [`voluntary_exit`](#voluntary_exit)
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- [`proposer_slashing`](#proposer_slashing)
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- [`attester_slashing`](#attester_slashing)
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- [Attestation subnets](#attestation-subnets)
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- [`beacon_attestation_{subnet_id}`](#beacon_attestation_subnet_id)
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- [Attestations and Aggregation](#attestations-and-aggregation)
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- [Encodings](#encodings)
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- [The Req/Resp domain](#the-reqresp-domain)
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- [Protocol identification](#protocol-identification)
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- [Req/Resp interaction](#reqresp-interaction)
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- [Requesting side](#requesting-side)
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- [Responding side](#responding-side)
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- [Encoding strategies](#encoding-strategies)
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- [SSZ-snappy encoding strategy](#ssz-snappy-encoding-strategy)
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- [Messages](#messages)
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- [Status](#status)
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- [Goodbye](#goodbye)
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- [BeaconBlocksByRange](#beaconblocksbyrange)
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- [BeaconBlocksByRoot](#beaconblocksbyroot)
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- [Ping](#ping)
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- [GetMetaData](#getmetadata)
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- [The discovery domain: discv5](#the-discovery-domain-discv5)
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- [Integration into libp2p stacks](#integration-into-libp2p-stacks)
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- [ENR structure](#enr-structure)
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- [Attestation subnet bitfield](#attestation-subnet-bitfield)
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- [`eth2` field](#eth2-field)
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- [General capabilities](#general-capabilities)
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- [Topic advertisement](#topic-advertisement)
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- [Design decision rationale](#design-decision-rationale)
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- [Transport](#transport-1)
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- [Why are we defining specific transports?](#why-are-we-defining-specific-transports)
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- [Can clients support other transports/handshakes than the ones mandated by the spec?](#can-clients-support-other-transportshandshakes-than-the-ones-mandated-by-the-spec)
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- [What are the advantages of using TCP/QUIC/Websockets?](#what-are-the-advantages-of-using-tcpquicwebsockets)
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- [Why do we not just support a single transport?](#why-do-we-not-just-support-a-single-transport)
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- [Why are we not using QUIC from the start?](#why-are-we-not-using-quic-from-the-start)
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- [Multiplexing](#multiplexing-1)
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- [Why are we using mplex/yamux?](#why-are-we-using-mplexyamux)
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- [Protocol Negotiation](#protocol-negotiation-1)
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- [When is multiselect 2.0 due and why do we plan to migrate to it?](#when-is-multiselect-20-due-and-why-do-we-plan-to-migrate-to-it)
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- [What is the difference between connection-level and stream-level protocol negotiation?](#what-is-the-difference-between-connection-level-and-stream-level-protocol-negotiation)
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- [Encryption](#encryption)
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- [Why are we not supporting SecIO?](#why-are-we-not-supporting-secio)
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- [Why are we using Noise?](#why-are-we-using-noise)
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- [Why are we using encryption at all?](#why-are-we-using-encryption-at-all)
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- [Gossipsub](#gossipsub)
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- [Why are we using a pub/sub algorithm for block and attestation propagation?](#why-are-we-using-a-pubsub-algorithm-for-block-and-attestation-propagation)
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- [Why are we using topics to segregate encodings, yet only support one encoding?](#why-are-we-using-topics-to-segregate-encodings-yet-only-support-one-encoding)
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- [How do we upgrade gossip channels (e.g. changes in encoding, compression)?](#how-do-we-upgrade-gossip-channels-eg-changes-in-encoding-compression)
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- [Why must all clients use the same gossip topic instead of one negotiated between each peer pair?](#why-must-all-clients-use-the-same-gossip-topic-instead-of-one-negotiated-between-each-peer-pair)
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- [Why are the topics strings and not hashes?](#why-are-the-topics-strings-and-not-hashes)
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- [Why are we overriding the default libp2p pubsub `message-id`?](#why-are-we-overriding-the-default-libp2p-pubsub-message-id)
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- [Why are these specific gossip parameters chosen?](#why-are-these-specific-gossip-parameters-chosen)
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- [Why is there `MAXIMUM_GOSSIP_CLOCK_DISPARITY` when validating slot ranges of messages in gossip subnets?](#why-is-there-maximum_gossip_clock_disparity-when-validating-slot-ranges-of-messages-in-gossip-subnets)
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- [Why are there `ATTESTATION_SUBNET_COUNT` attestation subnets?](#why-are-there-attestation_subnet_count-attestation-subnets)
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- [Why are attestations limited to be broadcast on gossip channels within `SLOTS_PER_EPOCH` slots?](#why-are-attestations-limited-to-be-broadcast-on-gossip-channels-within-slots_per_epoch-slots)
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- [Why are aggregate attestations broadcast to the global topic as `AggregateAndProof`s rather than just as `Attestation`s?](#why-are-aggregate-attestations-broadcast-to-the-global-topic-as-aggregateandproofs-rather-than-just-as-attestations)
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- [Why are we sending entire objects in the pubsub and not just hashes?](#why-are-we-sending-entire-objects-in-the-pubsub-and-not-just-hashes)
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- [Should clients gossip blocks if they *cannot* validate the proposer signature due to not yet being synced, not knowing the head block, etc?](#should-clients-gossip-blocks-if-they-cannot-validate-the-proposer-signature-due-to-not-yet-being-synced-not-knowing-the-head-block-etc)
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- [How are we going to discover peers in a gossipsub topic?](#how-are-we-going-to-discover-peers-in-a-gossipsub-topic)
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- [How should fork version be used in practice?](#how-should-fork-version-be-used-in-practice)
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- [Req/Resp](#reqresp)
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- [Why segregate requests into dedicated protocol IDs?](#why-segregate-requests-into-dedicated-protocol-ids)
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- [Why are messages length-prefixed with a protobuf varint in the SSZ-encoding?](#why-are-messages-length-prefixed-with-a-protobuf-varint-in-the-ssz-encoding)
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- [Why do we version protocol strings with ordinals instead of semver?](#why-do-we-version-protocol-strings-with-ordinals-instead-of-semver)
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- [Why is it called Req/Resp and not RPC?](#why-is-it-called-reqresp-and-not-rpc)
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- [Why do we allow empty responses in block requests?](#why-do-we-allow-empty-responses-in-block-requests)
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- [Why does `BeaconBlocksByRange` let the server choose which branch to send blocks from?](#why-does-beaconblocksbyrange-let-the-server-choose-which-branch-to-send-blocks-from)
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- [What's the effect of empty slots on the sync algorithm?](#whats-the-effect-of-empty-slots-on-the-sync-algorithm)
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- [Discovery](#discovery)
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- [Why are we using discv5 and not libp2p Kademlia DHT?](#why-are-we-using-discv5-and-not-libp2p-kademlia-dht)
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- [What is the difference between an ENR and a multiaddr, and why are we using ENRs?](#what-is-the-difference-between-an-enr-and-a-multiaddr-and-why-are-we-using-enrs)
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- [Why do we not form ENRs and find peers until genesis block/state is known?](#why-do-we-not-form-enrs-and-find-peers-until-genesis-blockstate-is-known)
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- [Compression/Encoding](#compressionencoding)
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- [Why are we using SSZ for encoding?](#why-are-we-using-ssz-for-encoding)
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- [Why are we compressing, and at which layers?](#why-are-we-compressing-and-at-which-layers)
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- [Why are using Snappy for compression?](#why-are-using-snappy-for-compression)
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- [Can I get access to unencrypted bytes on the wire for debugging purposes?](#can-i-get-access-to-unencrypted-bytes-on-the-wire-for-debugging-purposes)
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- [What are SSZ type size bounds?](#what-are-ssz-type-size-bounds)
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- [libp2p implementations matrix](#libp2p-implementations-matrix)
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<!-- END doctoc generated TOC please keep comment here to allow auto update -->
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<!-- /TOC -->
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# Network fundamentals
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This section outlines the specification for the networking stack in Ethereum 2.0 clients.
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## Transport
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Even though libp2p is a multi-transport stack (designed to listen on multiple simultaneous transports and endpoints transparently),
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we hereby define a profile for basic interoperability.
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All implementations MUST support the TCP libp2p transport, and it MUST be enabled for both dialing and listening (i.e. outbound and inbound connections).
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The libp2p TCP transport supports listening on IPv4 and IPv6 addresses (and on multiple simultaneously).
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Clients must support listening on at least one of IPv4 or IPv6.
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Clients that do _not_ have support for listening on IPv4 SHOULD be cognizant of the potential disadvantages in terms of
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Internet-wide routability/support. Clients MAY choose to listen only on IPv6, but MUST be capable of dialing both IPv4 and IPv6 addresses.
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All listening endpoints must be publicly dialable, and thus not rely on libp2p circuit relay, AutoNAT, or AutoRelay facilities.
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(Usage of circuit relay, AutoNAT, or AutoRelay will be specifically re-examined soon.)
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Nodes operating behind a NAT, or otherwise undialable by default (e.g. container runtime, firewall, etc.),
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MUST have their infrastructure configured to enable inbound traffic on the announced public listening endpoint.
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## Encryption and identification
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The [Libp2p-noise](https://github.com/libp2p/specs/tree/master/noise) secure
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channel handshake with `secp256k1` identities will be used for encryption.
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As specified in the libp2p specification, clients MUST support the `XX` handshake pattern.
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## Protocol Negotiation
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Clients MUST use exact equality when negotiating protocol versions to use and MAY use the version to give priority to higher version numbers.
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Clients MUST support [multistream-select 1.0](https://github.com/multiformats/multistream-select/)
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and MAY support [multiselect 2.0](https://github.com/libp2p/specs/pull/95) when the spec solidifies.
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Once all clients have implementations for multiselect 2.0, multistream-select 1.0 MAY be phased out.
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## Multiplexing
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During connection bootstrapping, libp2p dynamically negotiates a mutually supported multiplexing method to conduct parallel conversations.
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This applies to transports that are natively incapable of multiplexing (e.g. TCP, WebSockets, WebRTC),
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and is omitted for capable transports (e.g. QUIC).
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Two multiplexers are commonplace in libp2p implementations:
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[mplex](https://github.com/libp2p/specs/tree/master/mplex) and [yamux](https://github.com/hashicorp/yamux/blob/master/spec.md).
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Their protocol IDs are, respectively: `/mplex/6.7.0` and `/yamux/1.0.0`.
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Clients MUST support [mplex](https://github.com/libp2p/specs/tree/master/mplex)
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and MAY support [yamux](https://github.com/hashicorp/yamux/blob/master/spec.md).
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If both are supported by the client, yamux MUST take precedence during negotiation.
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See the [Rationale](#design-decision-rationale) section below for tradeoffs.
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# Eth2 network interaction domains
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## Configuration
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This section outlines constants that are used in this spec.
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| Name | Value | Description |
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|---|---|---|
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| `GOSSIP_MAX_SIZE` | `2**20` (= 1048576, 1 MiB) | The maximum allowed size of uncompressed gossip messages. |
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| `MAX_REQUEST_BLOCKS` | `2**10` (= 1024) | Maximum number of blocks in a single request |
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| `MAX_CHUNK_SIZE` | `2**20` (1048576, 1 MiB) | The maximum allowed size of uncompressed req/resp chunked responses. |
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| `TTFB_TIMEOUT` | `5s` | The maximum time to wait for first byte of request response (time-to-first-byte). |
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| `RESP_TIMEOUT` | `10s` | The maximum time for complete response transfer. |
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| `ATTESTATION_PROPAGATION_SLOT_RANGE` | `32` | The maximum number of slots during which an attestation can be propagated. |
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| `MAXIMUM_GOSSIP_CLOCK_DISPARITY` | `500ms` | The maximum milliseconds of clock disparity assumed between honest nodes. |
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## MetaData
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Clients MUST locally store the following `MetaData`:
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```
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(
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seq_number: uint64
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attnets: Bitvector[ATTESTATION_SUBNET_COUNT]
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)
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```
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Where
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- `seq_number` is a `uint64` starting at `0` used to version the node's metadata.
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If any other field in the local `MetaData` changes, the node MUST increment `seq_number` by 1.
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- `attnets` is a `Bitvector` representing the node's persistent attestation subnet subscriptions.
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*Note*: `MetaData.seq_number` is used for versioning of the node's metadata,
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is entirely independent of the ENR sequence number,
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and will in most cases be out of sync with the ENR sequence number.
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## The gossip domain: gossipsub
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Clients MUST support the [gossipsub v1](https://github.com/libp2p/specs/blob/master/pubsub/gossipsub/gossipsub-v1.0.md) libp2p Protocol
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including the [gossipsub v1.1](https://github.com/libp2p/specs/blob/master/pubsub/gossipsub/gossipsub-v1.1.md) extension.
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**Protocol ID:** `/meshsub/1.1.0`
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**Gossipsub Parameters**
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*Note*: Parameters listed here are subject to a large-scale network feasibility study.
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The following gossipsub [parameters](https://github.com/libp2p/specs/blob/master/pubsub/gossipsub/gossipsub-v1.0.md#parameters) will be used:
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- `D` (topic stable mesh target count): 6
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- `D_low` (topic stable mesh low watermark): 5
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- `D_high` (topic stable mesh high watermark): 12
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- `D_lazy` (gossip target): 6
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- `heartbeat_interval` (frequency of heartbeat, seconds): 0.7
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- `fanout_ttl` (ttl for fanout maps for topics we are not subscribed to but have published to, seconds): 60
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- `mcache_len` (number of windows to retain full messages in cache for `IWANT` responses): 6
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- `mcache_gossip` (number of windows to gossip about): 3
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- `seen_ttl` (number of heartbeat intervals to retain message IDs): 550
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### Topics and messages
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Topics are plain UTF-8 strings and are encoded on the wire as determined by protobuf (gossipsub messages are enveloped in protobuf messages).
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Topic strings have form: `/eth2/ForkDigestValue/Name/Encoding`.
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This defines both the type of data being sent on the topic and how the data field of the message is encoded.
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- `ForkDigestValue` - the lowercase hex-encoded (no "0x" prefix) bytes of `compute_fork_digest(current_fork_version, genesis_validators_root)` where
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- `current_fork_version` is the fork version of the epoch of the message to be sent on the topic
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- `genesis_validators_root` is the static `Root` found in `state.genesis_validators_root`
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- `Name` - see table below
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- `Encoding` - the encoding strategy describes a specific representation of bytes that will be transmitted over the wire.
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See the [Encodings](#Encodings) section for further details.
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*Note*: `ForkDigestValue` is composed of values that are not known until the genesis block/state are available.
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Due to this, clients SHOULD NOT subscribe to gossipsub topics until these genesis values are known.
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Each gossipsub [message](https://github.com/libp2p/go-libp2p-pubsub/blob/master/pb/rpc.proto#L17-L24) has a maximum size of `GOSSIP_MAX_SIZE`.
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Clients MUST reject (fail validation) messages that are over this size limit.
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Likewise, clients MUST NOT emit or propagate messages larger than this limit.
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The `message-id` of a gossipsub message MUST be:
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```python
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message-id: base64(SHA256(message.data))
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```
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where `base64` is the [URL-safe base64 alphabet](https://tools.ietf.org/html/rfc4648#section-3.2) with padding characters omitted.
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The payload is carried in the `data` field of a gossipsub message, and varies depending on the topic:
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| Name | Message Type |
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|----------------------------------|---------------------------|
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| `beacon_block` | `SignedBeaconBlock` |
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| `beacon_aggregate_and_proof` | `SignedAggregateAndProof` |
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| `beacon_attestation_{subnet_id}` | `Attestation` |
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| `voluntary_exit` | `SignedVoluntaryExit` |
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| `proposer_slashing` | `ProposerSlashing` |
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| `attester_slashing` | `AttesterSlashing` |
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Clients MUST reject (fail validation) messages containing an incorrect type, or invalid payload.
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When processing incoming gossip, clients MAY descore or disconnect peers who fail to observe these constraints.
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For any optional queueing, clients SHOULD maintain maximum queue sizes to avoid DoS vectors.
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Gossipsub v1.1 introduces [Extended Validators](https://github.com/libp2p/specs/blob/master/pubsub/gossipsub/gossipsub-v1.1.md#extended-validators)
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for the application to aid in the gossipsub peer-scoring scheme.
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We utilize `ACCEPT`, `REJECT`, and `IGNORE`. For each gossipsub topic, there are application specific validations.
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If all validations pass, return `ACCEPT`.
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If one or more validations fail while processing the items in order, return either `REJECT` or `IGNORE` as specified in the prefix of the particular condition.
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#### Global topics
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There are two primary global topics used to propagate beacon blocks (`beacon_block`)
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and aggregate attestations (`beacon_aggregate_and_proof`) to all nodes on the network.
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There are three additional global topics are used to propagate lower frequency validator messages
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(`voluntary_exit`, `proposer_slashing`, and `attester_slashing`).
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##### `beacon_block`
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The `beacon_block` topic is used solely for propagating new signed beacon blocks to all nodes on the networks.
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Signed blocks are sent in their entirety.
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The following validations MUST pass before forwarding the `signed_beacon_block` on the network.
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- _[IGNORE]_ The block is not from a future slot (with a `MAXIMUM_GOSSIP_CLOCK_DISPARITY` allowance) --
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i.e. validate that `signed_beacon_block.message.slot <= current_slot`
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(a client MAY queue future blocks for processing at the appropriate slot).
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- _[IGNORE]_ The block is from a slot greater than the latest finalized slot --
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i.e. validate that `signed_beacon_block.message.slot > compute_start_slot_at_epoch(state.finalized_checkpoint.epoch)`
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(a client MAY choose to validate and store such blocks for additional purposes -- e.g. slashing detection, archive nodes, etc).
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- _[IGNORE]_ The block is the first block with valid signature received for the proposer for the slot, `signed_beacon_block.message.slot`.
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- _[REJECT]_ The proposer signature, `signed_beacon_block.signature`, is valid with respect to the `proposer_index` pubkey.
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- _[IGNORE]_ The block's parent (defined by `block.parent_root`) has been seen
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(via both gossip and non-gossip sources)
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(a client MAY queue blocks for processing once the parent block is retrieved).
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- _[REJECT]_ The block's parent (defined by `block.parent_root`) passes validation.
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- _[REJECT]_ The current `finalized_checkpoint` is an ancestor of `block` -- i.e.
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`get_ancestor(store, block.parent_root, compute_start_slot_at_epoch(store.finalized_checkpoint.epoch))
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== store.finalized_checkpoint.root`
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- _[REJECT]_ The block is proposed by the expected `proposer_index` for the block's slot
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in the context of the current shuffling (defined by `parent_root`/`slot`).
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If the `proposer_index` cannot immediately be verified against the expected shuffling,
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the block MAY be queued for later processing while proposers for the block's branch are calculated --
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in such a case _do not_ `REJECT`, instead `IGNORE` this message.
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##### `beacon_aggregate_and_proof`
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The `beacon_aggregate_and_proof` topic is used to propagate aggregated attestations (as `SignedAggregateAndProof`s)
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to subscribing nodes (typically validators) to be included in future blocks.
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The following validations MUST pass before forwarding the `signed_aggregate_and_proof` on the network.
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(We define the following for convenience -- `aggregate_and_proof = signed_aggregate_and_proof.message` and `aggregate = aggregate_and_proof.aggregate`)
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- _[IGNORE]_ `aggregate.data.slot` is within the last `ATTESTATION_PROPAGATION_SLOT_RANGE` slots (with a `MAXIMUM_GOSSIP_CLOCK_DISPARITY` allowance) --
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i.e. `aggregate.data.slot + ATTESTATION_PROPAGATION_SLOT_RANGE >= current_slot >= aggregate.data.slot`
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(a client MAY queue future aggregates for processing at the appropriate slot).
|
||
- _[IGNORE]_ The valid aggregate attestation defined by `hash_tree_root(aggregate)` has _not_ already been seen
|
||
(via aggregate gossip, within a verified block, or through the creation of an equivalent aggregate locally).
|
||
- _[IGNORE]_ The `aggregate` is the first valid aggregate received for the aggregator
|
||
with index `aggregate_and_proof.aggregator_index` for the epoch `aggregate.data.target.epoch`.
|
||
- _[REJECT]_ The attestation has participants --
|
||
that is, `len(get_attesting_indices(state, aggregate.data, aggregate.aggregation_bits)) >= 1`.
|
||
- _[REJECT]_ `aggregate_and_proof.selection_proof` selects the validator as an aggregator for the slot --
|
||
i.e. `is_aggregator(state, aggregate.data.slot, aggregate.data.index, aggregate_and_proof.selection_proof)` returns `True`.
|
||
- _[REJECT]_ The aggregator's validator index is within the committee --
|
||
i.e. `aggregate_and_proof.aggregator_index in get_beacon_committee(state, aggregate.data.slot, aggregate.data.index)`.
|
||
- _[REJECT]_ The `aggregate_and_proof.selection_proof` is a valid signature
|
||
of the `aggregate.data.slot` by the validator with index `aggregate_and_proof.aggregator_index`.
|
||
- _[REJECT]_ The aggregator signature, `signed_aggregate_and_proof.signature`, is valid.
|
||
- _[REJECT]_ The signature of `aggregate` is valid.
|
||
- _[IGNORE]_ The block being voted for (`aggregate.data.beacon_block_root`) has been seen
|
||
(via both gossip and non-gossip sources)
|
||
(a client MAY queue aggregates for processing once block is retrieved).
|
||
- _[REJECT]_ The block being voted for (`aggregate.data.beacon_block_root`) passes validation.
|
||
- _[REJECT]_ The current `finalized_checkpoint` is an ancestor of the `block` defined by `aggregate.data.beacon_block_root` -- i.e.
|
||
`get_ancestor(store, aggregate.data.beacon_block_root, compute_start_slot_at_epoch(store.finalized_checkpoint.epoch))
|
||
== store.finalized_checkpoint.root`
|
||
|
||
|
||
##### `voluntary_exit`
|
||
|
||
The `voluntary_exit` topic is used solely for propagating signed voluntary validator exits to proposers on the network.
|
||
Signed voluntary exits are sent in their entirety.
|
||
|
||
The following validations MUST pass before forwarding the `signed_voluntary_exit` on to the network.
|
||
- _[IGNORE]_ The voluntary exit is the first valid voluntary exit received
|
||
for the validator with index `signed_voluntary_exit.message.validator_index`.
|
||
- _[REJECT]_ All of the conditions within `process_voluntary_exit` pass validation.
|
||
|
||
##### `proposer_slashing`
|
||
|
||
The `proposer_slashing` topic is used solely for propagating proposer slashings to proposers on the network.
|
||
Proposer slashings are sent in their entirety.
|
||
|
||
The following validations MUST pass before forwarding the `proposer_slashing` on to the network.
|
||
- _[IGNORE]_ The proposer slashing is the first valid proposer slashing received
|
||
for the proposer with index `proposer_slashing.signed_header_1.message.proposer_index`.
|
||
- _[REJECT]_ All of the conditions within `process_proposer_slashing` pass validation.
|
||
|
||
##### `attester_slashing`
|
||
|
||
The `attester_slashing` topic is used solely for propagating attester slashings to proposers on the network.
|
||
Attester slashings are sent in their entirety.
|
||
|
||
Clients who receive an attester slashing on this topic MUST validate the conditions within `process_attester_slashing` before forwarding it across the network.
|
||
- _[IGNORE]_ At least one index in the intersection of the attesting indices of each attestation
|
||
has not yet been seen in any prior `attester_slashing`
|
||
(i.e. `attester_slashed_indices = set(attestation_1.attesting_indices).intersection(attestation_2.attesting_indices)`,
|
||
verify if `any(attester_slashed_indices.difference(prior_seen_attester_slashed_indices))`).
|
||
- _[REJECT]_ All of the conditions within `process_attester_slashing` pass validation.
|
||
|
||
#### Attestation subnets
|
||
|
||
Attestation subnets are used to propagate unaggregated attestations to subsections of the network.
|
||
|
||
##### `beacon_attestation_{subnet_id}`
|
||
|
||
The `beacon_attestation_{subnet_id}` topics are used to propagate unaggregated attestations
|
||
to the subnet `subnet_id` (typically beacon and persistent committees) to be aggregated before being gossiped to `beacon_aggregate_and_proof`.
|
||
|
||
The following validations MUST pass before forwarding the `attestation` on the subnet.
|
||
- _[REJECT]_ The attestation is for the correct subnet --
|
||
i.e. `compute_subnet_for_attestation(committees_per_slot, attestation.data.slot, attestation.data.index) == subnet_id`,
|
||
where `committees_per_slot = get_committee_count_per_slot(state, attestation.data.target.epoch)`,
|
||
which may be pre-computed along with the committee information for the signature check.
|
||
- _[IGNORE]_ `attestation.data.slot` is within the last `ATTESTATION_PROPAGATION_SLOT_RANGE` slots
|
||
(within a `MAXIMUM_GOSSIP_CLOCK_DISPARITY` allowance) --
|
||
i.e. `attestation.data.slot + ATTESTATION_PROPAGATION_SLOT_RANGE >= current_slot >= attestation.data.slot`
|
||
(a client MAY queue future attestations for processing at the appropriate slot).
|
||
- _[REJECT]_ The attestation's epoch matches its target -- i.e. `attestation.data.target.epoch ==
|
||
compute_epoch_at_slot(attestation.data.slot)`
|
||
- _[REJECT]_ The attestation is unaggregated --
|
||
that is, it has exactly one participating validator (`len([bit for bit in attestation.aggregation_bits if bit]) == 1`, i.e. exactly 1 bit is set).
|
||
- _[IGNORE]_ There has been no other valid attestation seen on an attestation subnet
|
||
that has an identical `attestation.data.target.epoch` and participating validator index.
|
||
- _[REJECT]_ The signature of `attestation` is valid.
|
||
- _[IGNORE]_ The block being voted for (`attestation.data.beacon_block_root`) has been seen
|
||
(via both gossip and non-gossip sources)
|
||
(a client MAY queue aggregates for processing once block is retrieved).
|
||
- _[REJECT]_ The block being voted for (`attestation.data.beacon_block_root`) passes validation.
|
||
- _[REJECT]_ The attestation's target block is an ancestor of the block named in the LMD vote -- i.e.
|
||
`get_ancestor(store, attestation.data.beacon_block_root, compute_start_slot_at_epoch(attestation.data.target.epoch)) == attestation.data.target.root`
|
||
- _[REJECT]_ The current `finalized_checkpoint` is an ancestor of the `block` defined by `attestation.data.beacon_block_root` -- i.e.
|
||
`get_ancestor(store, attestation.data.beacon_block_root, compute_start_slot_at_epoch(store.finalized_checkpoint.epoch))
|
||
== store.finalized_checkpoint.root`
|
||
|
||
|
||
|
||
|
||
#### Attestations and Aggregation
|
||
|
||
Attestation broadcasting is grouped into subnets defined by a topic.
|
||
The number of subnets is defined via `ATTESTATION_SUBNET_COUNT`.
|
||
The correct subnet for an attestation can be calculated with `compute_subnet_for_attestation`.
|
||
`beacon_attestation_{subnet_id}` topics, are rotated through throughout the epoch in a similar fashion to rotating through shards in committees in Phase 1.
|
||
The subnets are rotated through with `committees_per_slot = get_committee_count_per_slot(state, attestation.data.target.epoch)` subnets per slot.
|
||
|
||
Unaggregated attestations are sent as `Attestation`s to the subnet topic,
|
||
`beacon_attestation_{compute_subnet_for_attestation(committees_per_slot, attestation.data.slot, attestation.data.index)}` as `Attestation`s.
|
||
|
||
Aggregated attestations are sent to the `beacon_aggregate_and_proof` topic as `AggregateAndProof`s.
|
||
|
||
### Encodings
|
||
|
||
Topics are post-fixed with an encoding. Encodings define how the payload of a gossipsub message is encoded.
|
||
|
||
- `ssz_snappy` - All objects are SSZ-encoded and then compressed with [Snappy](https://github.com/google/snappy) block compression.
|
||
Example: The beacon aggregate attestation topic string is `/eth2/446a7232/beacon_aggregate_and_proof/ssz_snappy`,
|
||
the fork digest is `446a7232` and the data field of a gossipsub message is an `AggregateAndProof`
|
||
that has been SSZ-encoded and then compressed with Snappy.
|
||
|
||
Snappy has two formats: "block" and "frames" (streaming).
|
||
Gossip messages remain relatively small (100s of bytes to 100s of kilobytes)
|
||
so [basic snappy block compression](https://github.com/google/snappy/blob/master/format_description.txt) is used to avoid the additional overhead associated with snappy frames.
|
||
|
||
Implementations MUST use a single encoding for gossip.
|
||
Changing an encoding will require coordination between participating implementations.
|
||
|
||
## The Req/Resp domain
|
||
|
||
### Protocol identification
|
||
|
||
Each message type is segregated into its own libp2p protocol ID, which is a case-sensitive UTF-8 string of the form:
|
||
|
||
```
|
||
/ProtocolPrefix/MessageName/SchemaVersion/Encoding
|
||
```
|
||
|
||
With:
|
||
|
||
- `ProtocolPrefix` - messages are grouped into families identified by a shared libp2p protocol name prefix.
|
||
In this case, we use `/eth2/beacon_chain/req`.
|
||
- `MessageName` - each request is identified by a name consisting of English alphabet, digits and underscores (`_`).
|
||
- `SchemaVersion` - an ordinal version number (e.g. 1, 2, 3…).
|
||
Each schema is versioned to facilitate backward and forward-compatibility when possible.
|
||
- `Encoding` - while the schema defines the data types in more abstract terms,
|
||
the encoding strategy describes a specific representation of bytes that will be transmitted over the wire.
|
||
See the [Encodings](#Encoding-strategies) section for further details.
|
||
|
||
This protocol segregation allows libp2p `multistream-select 1.0` / `multiselect 2.0`
|
||
to handle the request type, version, and encoding negotiation before establishing the underlying streams.
|
||
|
||
### Req/Resp interaction
|
||
|
||
We use ONE stream PER request/response interaction.
|
||
Streams are closed when the interaction finishes, whether in success or in error.
|
||
|
||
Request/response messages MUST adhere to the encoding specified in the protocol name and follow this structure (relaxed BNF grammar):
|
||
|
||
```
|
||
request ::= <encoding-dependent-header> | <encoded-payload>
|
||
response ::= <response_chunk>*
|
||
response_chunk ::= <result> | <encoding-dependent-header> | <encoded-payload>
|
||
result ::= “0” | “1” | “2” | [“128” ... ”255”]
|
||
```
|
||
|
||
The encoding-dependent header may carry metadata or assertions such as the encoded payload length, for integrity and attack proofing purposes.
|
||
Because req/resp streams are single-use and stream closures implicitly delimit the boundaries, it is not strictly necessary to length-prefix payloads;
|
||
however, certain encodings like SSZ do, for added security.
|
||
|
||
A `response` is formed by zero or more `response_chunk`s.
|
||
Responses that consist of a single SSZ-list (such as `BlocksByRange` and `BlocksByRoot`) send each list item as a `response_chunk`.
|
||
All other response types (non-Lists) send a single `response_chunk`.
|
||
|
||
For both `request`s and `response`s, the `encoding-dependent-header` MUST be valid,
|
||
and the `encoded-payload` must be valid within the constraints of the `encoding-dependent-header`.
|
||
This includes type-specific bounds on payload size for some encoding strategies.
|
||
Regardless of these type specific bounds, a global maximum uncompressed byte size of `MAX_CHUNK_SIZE` MUST be applied to all method response chunks.
|
||
|
||
Clients MUST ensure that lengths are within these bounds; if not, they SHOULD reset the stream immediately.
|
||
Clients tracking peer reputation MAY decrement the score of the misbehaving peer under this circumstance.
|
||
|
||
#### Requesting side
|
||
|
||
Once a new stream with the protocol ID for the request type has been negotiated, the full request message SHOULD be sent immediately.
|
||
The request MUST be encoded according to the encoding strategy.
|
||
|
||
The requester MUST close the write side of the stream once it finishes writing the request message.
|
||
At this point, the stream will be half-closed.
|
||
|
||
The requester MUST wait a maximum of `TTFB_TIMEOUT` for the first response byte to arrive (time to first byte—or TTFB—timeout).
|
||
On that happening, the requester allows a further `RESP_TIMEOUT` for each subsequent `response_chunk` received.
|
||
|
||
If any of these timeouts fire, the requester SHOULD reset the stream and deem the req/resp operation to have failed.
|
||
|
||
A requester SHOULD read from the stream until either:
|
||
1. An error result is received in one of the chunks (the error payload MAY be read before stopping).
|
||
2. The responder closes the stream.
|
||
3. Any part of the `response_chunk` fails validation.
|
||
4. The maximum number of requested chunks are read.
|
||
|
||
For requests consisting of a single valid `response_chunk`,
|
||
the requester SHOULD read the chunk fully, as defined by the `encoding-dependent-header`, before closing the stream.
|
||
|
||
#### Responding side
|
||
|
||
Once a new stream with the protocol ID for the request type has been negotiated,
|
||
the responder SHOULD process the incoming request and MUST validate it before processing it.
|
||
Request processing and validation MUST be done according to the encoding strategy, until EOF (denoting stream half-closure by the requester).
|
||
|
||
The responder MUST:
|
||
|
||
1. Use the encoding strategy to read the optional header.
|
||
2. If there are any length assertions for length `N`, it should read exactly `N` bytes from the stream, at which point an EOF should arise (no more bytes).
|
||
Should this not be the case, it should be treated as a failure.
|
||
3. Deserialize the expected type, and process the request.
|
||
4. Write the response which may consist of zero or more `response_chunk`s (result, optional header, payload).
|
||
5. Close their write side of the stream. At this point, the stream will be fully closed.
|
||
|
||
If steps (1), (2), or (3) fail due to invalid, malformed, or inconsistent data, the responder MUST respond in error.
|
||
Clients tracking peer reputation MAY record such failures, as well as unexpected events, e.g. early stream resets.
|
||
|
||
The entire request should be read in no more than `RESP_TIMEOUT`.
|
||
Upon a timeout, the responder SHOULD reset the stream.
|
||
|
||
The responder SHOULD send a `response_chunk` promptly.
|
||
Chunks start with a **single-byte** response code which determines the contents of the `response_chunk` (`result` particle in the BNF grammar above).
|
||
For multiple chunks, only the last chunk is allowed to have a non-zero error code (i.e. The chunk stream is terminated once an error occurs).
|
||
|
||
The response code can have one of the following values, encoded as a single unsigned byte:
|
||
|
||
- 0: **Success** -- a normal response follows, with contents matching the expected message schema and encoding specified in the request.
|
||
- 1: **InvalidRequest** -- the contents of the request are semantically invalid, or the payload is malformed, or could not be understood.
|
||
The response payload adheres to the `ErrorMessage` schema (described below).
|
||
- 2: **ServerError** -- the responder encountered an error while processing the request.
|
||
The response payload adheres to the `ErrorMessage` schema (described below).
|
||
|
||
Clients MAY use response codes above `128` to indicate alternative, erroneous request-specific responses.
|
||
|
||
The range `[3, 127]` is RESERVED for future usages, and should be treated as error if not recognized expressly.
|
||
|
||
The `ErrorMessage` schema is:
|
||
|
||
```
|
||
(
|
||
error_message: List[byte, 256]
|
||
)
|
||
```
|
||
|
||
*Note*: By convention, the `error_message` is a sequence of bytes that MAY be interpreted as a UTF-8 string (for debugging purposes).
|
||
Clients MUST treat as valid any byte sequences.
|
||
|
||
### Encoding strategies
|
||
|
||
The token of the negotiated protocol ID specifies the type of encoding to be used for the req/resp interaction.
|
||
Only one value is possible at this time:
|
||
|
||
- `ssz_snappy`: The contents are first [SSZ-encoded](../../ssz/simple-serialize.md)
|
||
and then compressed with [Snappy](https://github.com/google/snappy) frames compression.
|
||
For objects containing a single field, only the field is SSZ-encoded not a container with a single field.
|
||
For example, the `BeaconBlocksByRoot` request is an SSZ-encoded list of `Root`'s.
|
||
This encoding type MUST be supported by all clients.
|
||
|
||
#### SSZ-snappy encoding strategy
|
||
|
||
The [SimpleSerialize (SSZ) specification](../../ssz/simple-serialize.md) outlines how objects are SSZ-encoded.
|
||
|
||
To achieve snappy encoding on top of SSZ, we feed the serialized form of the object to the Snappy compressor on encoding.
|
||
The inverse happens on decoding.
|
||
|
||
Snappy has two formats: "block" and "frames" (streaming).
|
||
To support large requests and response chunks, snappy-framing is used.
|
||
|
||
Since snappy frame contents [have a maximum size of `65536` bytes](https://github.com/google/snappy/blob/master/framing_format.txt#L104)
|
||
and frame headers are just `identifier (1) + checksum (4)` bytes, the expected buffering of a single frame is acceptable.
|
||
|
||
**Encoding-dependent header:** Req/Resp protocols using the `ssz_snappy` encoding strategy MUST encode the length of the raw SSZ bytes,
|
||
encoded as an unsigned [protobuf varint](https://developers.google.com/protocol-buffers/docs/encoding#varints).
|
||
|
||
*Writing*: By first computing and writing the SSZ byte length, the SSZ encoder can then directly write the chunk contents to the stream.
|
||
When Snappy is applied, it can be passed through a buffered Snappy writer to compress frame by frame.
|
||
|
||
*Reading*: After reading the expected SSZ byte length, the SSZ decoder can directly read the contents from the stream.
|
||
When snappy is applied, it can be passed through a buffered Snappy reader to decompress frame by frame.
|
||
|
||
Before reading the payload, the header MUST be validated:
|
||
- The unsigned protobuf varint used for the length-prefix MUST not be longer than 10 bytes, which is sufficient for any `uint64`.
|
||
- The length-prefix is within the expected [size bounds derived from the payload SSZ type](#what-are-ssz-type-size-bounds).
|
||
|
||
After reading a valid header, the payload MAY be read, while maintaining the size constraints from the header.
|
||
|
||
A reader SHOULD NOT read more than `max_encoded_len(n)` bytes after reading the SSZ length-prefix `n` from the header.
|
||
- For `ssz_snappy` this is: `32 + n + n // 6`.
|
||
This is considered the [worst-case compression result](https://github.com/google/snappy/blob/537f4ad6240e586970fe554614542e9717df7902/snappy.cc#L98) by Snappy.
|
||
|
||
A reader SHOULD consider the following cases as invalid input:
|
||
- Any remaining bytes, after having read the `n` SSZ bytes. An EOF is expected if more bytes are read than required.
|
||
- An early EOF, before fully reading the declared length-prefix worth of SSZ bytes.
|
||
|
||
In case of an invalid input (header or payload), a reader MUST:
|
||
- From requests: send back an error message, response code `InvalidRequest`. The request itself is ignored.
|
||
- From responses: ignore the response, the response MUST be considered bad server behavior.
|
||
|
||
All messages that contain only a single field MUST be encoded directly as the type of that field and MUST NOT be encoded as an SSZ container.
|
||
|
||
Responses that are SSZ-lists (for example `List[SignedBeaconBlock, ...]`) send their
|
||
constituents individually as `response_chunk`s. For example, the
|
||
`List[SignedBeaconBlock, ...]` response type sends zero or more `response_chunk`s.
|
||
Each _successful_ `response_chunk` contains a single `SignedBeaconBlock` payload.
|
||
|
||
### Messages
|
||
|
||
#### Status
|
||
|
||
**Protocol ID:** ``/eth2/beacon_chain/req/status/1/``
|
||
|
||
Request, Response Content:
|
||
```
|
||
(
|
||
fork_digest: ForkDigest
|
||
finalized_root: Root
|
||
finalized_epoch: Epoch
|
||
head_root: Root
|
||
head_slot: Slot
|
||
)
|
||
```
|
||
The fields are, as seen by the client at the time of sending the message:
|
||
|
||
- `fork_digest`: The node's `ForkDigest` (`compute_fork_digest(current_fork_version, genesis_validators_root)`) where
|
||
- `current_fork_version` is the fork version at the node's current epoch defined by the wall-clock time
|
||
(not necessarily the epoch to which the node is sync)
|
||
- `genesis_validators_root` is the static `Root` found in `state.genesis_validators_root`
|
||
- `finalized_root`: `state.finalized_checkpoint.root` for the state corresponding to the head block
|
||
(Note this defaults to `Root(b'\x00' * 32)` for the genesis finalized checkpoint).
|
||
- `finalized_epoch`: `state.finalized_checkpoint.epoch` for the state corresponding to the head block.
|
||
- `head_root`: The `hash_tree_root` root of the current head block (`BeaconBlock`).
|
||
- `head_slot`: The slot of the block corresponding to the `head_root`.
|
||
|
||
The dialing client MUST send a `Status` request upon connection.
|
||
|
||
The request/response MUST be encoded as an SSZ-container.
|
||
|
||
The response MUST consist of a single `response_chunk`.
|
||
|
||
Clients SHOULD immediately disconnect from one another following the handshake above under the following conditions:
|
||
|
||
1. If `fork_digest` does not match the node's local `fork_digest`, since the client’s chain is on another fork.
|
||
2. If the (`finalized_root`, `finalized_epoch`) shared by the peer is not in the client's chain at the expected epoch.
|
||
For example, if Peer 1 sends (root, epoch) of (A, 5) and Peer 2 sends (B, 3) but Peer 1 has root C at epoch 3,
|
||
then Peer 1 would disconnect because it knows that their chains are irreparably disjoint.
|
||
|
||
Once the handshake completes, the client with the lower `finalized_epoch` or `head_slot` (if the clients have equal `finalized_epoch`s)
|
||
SHOULD request beacon blocks from its counterparty via the `BeaconBlocksByRange` request.
|
||
|
||
*Note*: Under abnormal network condition or after some rounds of `BeaconBlocksByRange` requests,
|
||
the client might need to send `Status` request again to learn if the peer has a higher head.
|
||
Implementers are free to implement such behavior in their own way.
|
||
|
||
#### Goodbye
|
||
|
||
**Protocol ID:** ``/eth2/beacon_chain/req/goodbye/1/``
|
||
|
||
Request, Response Content:
|
||
```
|
||
(
|
||
uint64
|
||
)
|
||
```
|
||
Client MAY send goodbye messages upon disconnection. The reason field MAY be one of the following values:
|
||
|
||
- 1: Client shut down.
|
||
- 2: Irrelevant network.
|
||
- 3: Fault/error.
|
||
|
||
Clients MAY use reason codes above `128` to indicate alternative, erroneous request-specific responses.
|
||
|
||
The range `[4, 127]` is RESERVED for future usage.
|
||
|
||
The request/response MUST be encoded as a single SSZ-field.
|
||
|
||
The response MUST consist of a single `response_chunk`.
|
||
|
||
#### BeaconBlocksByRange
|
||
|
||
**Protocol ID:** `/eth2/beacon_chain/req/beacon_blocks_by_range/1/`
|
||
|
||
Request Content:
|
||
```
|
||
(
|
||
start_slot: Slot
|
||
count: uint64
|
||
step: uint64
|
||
)
|
||
```
|
||
|
||
Response Content:
|
||
```
|
||
(
|
||
List[SignedBeaconBlock, MAX_REQUEST_BLOCKS]
|
||
)
|
||
```
|
||
|
||
Requests beacon blocks in the slot range `[start_slot, start_slot + count * step)`, leading up to the current head block as selected by fork choice.
|
||
`step` defines the slot increment between blocks.
|
||
For example, requesting blocks starting at `start_slot` 2 with a step value of 2 would return the blocks at slots [2, 4, 6, …].
|
||
In cases where a slot is empty for a given slot number, no block is returned.
|
||
For example, if slot 4 were empty in the previous example, the returned array would contain [2, 6, …].
|
||
A request MUST NOT have a 0 slot increment, i.e. `step >= 1`.
|
||
|
||
`BeaconBlocksByRange` is primarily used to sync historical blocks.
|
||
|
||
The request MUST be encoded as an SSZ-container.
|
||
|
||
The response MUST consist of zero or more `response_chunk`.
|
||
Each _successful_ `response_chunk` MUST contain a single `SignedBeaconBlock` payload.
|
||
|
||
Clients MUST keep a record of signed blocks seen since the start of the weak subjectivity period
|
||
and MUST support serving requests of blocks up to their own `head_block_root`.
|
||
|
||
Clients MUST respond with at least the first block that exists in the range, if they have it, and no more than `MAX_REQUEST_BLOCKS` blocks.
|
||
|
||
The following blocks, where they exist, MUST be send in consecutive order.
|
||
|
||
Clients MAY limit the number of blocks in the response.
|
||
|
||
The response MUST contain no more than `count` blocks.
|
||
|
||
Clients MUST respond with blocks from their view of the current fork choice
|
||
-- that is, blocks from the single chain defined by the current head.
|
||
Of note, blocks from slots before the finalization MUST lead to the finalized block reported in the `Status` handshake.
|
||
|
||
Clients MUST respond with blocks that are consistent from a single chain within the context of the request.
|
||
This applies to any `step` value.
|
||
In particular when `step == 1`, each `parent_root` MUST match the `hash_tree_root` of the preceding block.
|
||
|
||
After the initial block, clients MAY stop in the process of responding
|
||
if their fork choice changes the view of the chain in the context of the request.
|
||
|
||
#### BeaconBlocksByRoot
|
||
|
||
**Protocol ID:** `/eth2/beacon_chain/req/beacon_blocks_by_root/1/`
|
||
|
||
Request Content:
|
||
|
||
```
|
||
(
|
||
List[Root, MAX_REQUEST_BLOCKS]
|
||
)
|
||
```
|
||
|
||
Response Content:
|
||
|
||
```
|
||
(
|
||
List[SignedBeaconBlock, MAX_REQUEST_BLOCKS]
|
||
)
|
||
```
|
||
|
||
Requests blocks by block root (= `hash_tree_root(SignedBeaconBlock.message)`).
|
||
The response is a list of `SignedBeaconBlock` whose length is less than or equal to the number of requested blocks.
|
||
It may be less in the case that the responding peer is missing blocks.
|
||
|
||
No more than `MAX_REQUEST_BLOCKS` may be requested at a time.
|
||
|
||
`BeaconBlocksByRoot` is primarily used to recover recent blocks (e.g. when receiving a block or attestation whose parent is unknown).
|
||
|
||
The request MUST be encoded as an SSZ-field.
|
||
|
||
The response MUST consist of zero or more `response_chunk`.
|
||
Each _successful_ `response_chunk` MUST contain a single `SignedBeaconBlock` payload.
|
||
|
||
Clients MUST support requesting blocks since the latest finalized epoch.
|
||
|
||
Clients MUST respond with at least one block, if they have it.
|
||
Clients MAY limit the number of blocks in the response.
|
||
|
||
#### Ping
|
||
|
||
**Protocol ID:** `/eth2/beacon_chain/req/ping/1/`
|
||
|
||
Request Content:
|
||
|
||
```
|
||
(
|
||
uint64
|
||
)
|
||
```
|
||
|
||
Response Content:
|
||
|
||
```
|
||
(
|
||
uint64
|
||
)
|
||
```
|
||
|
||
Sent intermittently, the `Ping` protocol checks liveness of connected peers.
|
||
Peers request and respond with their local metadata sequence number (`MetaData.seq_number`).
|
||
|
||
If the peer does not respond to the `Ping` request, the client MAY disconnect from the peer.
|
||
|
||
A client can then determine if their local record of a peer's MetaData is up to date
|
||
and MAY request an updated version via the `MetaData` RPC method if not.
|
||
|
||
The request MUST be encoded as an SSZ-field.
|
||
|
||
The response MUST consist of a single `response_chunk`.
|
||
|
||
#### GetMetaData
|
||
|
||
**Protocol ID:** `/eth2/beacon_chain/req/metadata/1/`
|
||
|
||
No Request Content.
|
||
|
||
Response Content:
|
||
|
||
```
|
||
(
|
||
MetaData
|
||
)
|
||
```
|
||
|
||
Requests the MetaData of a peer.
|
||
The request opens and negotiates the stream without sending any request content.
|
||
Once established the receiving peer responds with
|
||
it's local most up-to-date MetaData.
|
||
|
||
The response MUST be encoded as an SSZ-container.
|
||
|
||
The response MUST consist of a single `response_chunk`.
|
||
|
||
## The discovery domain: discv5
|
||
|
||
Discovery Version 5 ([discv5](https://github.com/ethereum/devp2p/blob/master/discv5/discv5.md)) is used for peer discovery.
|
||
|
||
`discv5` is a standalone protocol, running on UDP on a dedicated port, meant for peer discovery only.
|
||
`discv5` supports self-certified, flexible peer records (ENRs) and topic-based advertisement, both of which are (or will be) requirements in this context.
|
||
|
||
:warning: Under construction. :warning:
|
||
|
||
### Integration into libp2p stacks
|
||
|
||
`discv5` SHOULD be integrated into the client’s libp2p stack by implementing an adaptor
|
||
to make it conform to the [service discovery](https://github.com/libp2p/go-libp2p-core/blob/master/discovery/discovery.go)
|
||
and [peer routing](https://github.com/libp2p/go-libp2p-core/blob/master/routing/routing.go#L36-L44) abstractions and interfaces (go-libp2p links provided).
|
||
|
||
Inputs to operations include peer IDs (when locating a specific peer) or capabilities (when searching for peers with a specific capability),
|
||
and the outputs will be multiaddrs converted from the ENR records returned by the discv5 backend.
|
||
|
||
This integration enables the libp2p stack to subsequently form connections and streams with discovered peers.
|
||
|
||
### ENR structure
|
||
|
||
The Ethereum Node Record (ENR) for an Ethereum 2.0 client MUST contain the following entries
|
||
(exclusive of the sequence number and signature, which MUST be present in an ENR):
|
||
|
||
- The compressed secp256k1 publickey, 33 bytes (`secp256k1` field).
|
||
|
||
The ENR MAY contain the following entries:
|
||
|
||
- An IPv4 address (`ip` field) and/or IPv6 address (`ip6` field).
|
||
- A TCP port (`tcp` field) representing the local libp2p listening port.
|
||
- A UDP port (`udp` field) representing the local discv5 listening port.
|
||
|
||
Specifications of these parameters can be found in the [ENR Specification](http://eips.ethereum.org/EIPS/eip-778).
|
||
|
||
#### Attestation subnet bitfield
|
||
|
||
The ENR `attnets` entry signifies the attestation subnet bitfield with the following form
|
||
to more easily discover peers participating in particular attestation gossip subnets.
|
||
|
||
| Key | Value |
|
||
|:-------------|:-------------------------------------------------|
|
||
| `attnets` | SSZ `Bitvector[ATTESTATION_SUBNET_COUNT]` |
|
||
|
||
If a node's `MetaData.attnets` has any non-zero bit, the ENR MUST include the `attnets` entry with the same value as `MetaData.attnets`.
|
||
|
||
If a node's `MetaData.attnets` is composed of all zeros, the ENR MAY optionally include the `attnets` entry or leave it out entirely.
|
||
|
||
#### `eth2` field
|
||
|
||
ENRs MUST carry a generic `eth2` key with an 16-byte value of the node's current fork digest, next fork version,
|
||
and next fork epoch to ensure connections are made with peers on the intended eth2 network.
|
||
|
||
| Key | Value |
|
||
|:-------------|:--------------------|
|
||
| `eth2` | SSZ `ENRForkID` |
|
||
|
||
Specifically, the value of the `eth2` key MUST be the following SSZ encoded object (`ENRForkID`)
|
||
|
||
```
|
||
(
|
||
fork_digest: ForkDigest
|
||
next_fork_version: Version
|
||
next_fork_epoch: Epoch
|
||
)
|
||
```
|
||
|
||
where the fields of `ENRForkID` are defined as
|
||
|
||
* `fork_digest` is `compute_fork_digest(current_fork_version, genesis_validators_root)` where
|
||
* `current_fork_version` is the fork version at the node's current epoch defined by the wall-clock time
|
||
(not necessarily the epoch to which the node is sync)
|
||
* `genesis_validators_root` is the static `Root` found in `state.genesis_validators_root`
|
||
* `next_fork_version` is the fork version corresponding to the next planned hard fork at a future epoch.
|
||
If no future fork is planned, set `next_fork_version = current_fork_version` to signal this fact
|
||
* `next_fork_epoch` is the epoch at which the next fork is planned and the `current_fork_version` will be updated.
|
||
If no future fork is planned, set `next_fork_epoch = FAR_FUTURE_EPOCH` to signal this fact
|
||
|
||
*Note*: `fork_digest` is composed of values that are not not known until the genesis block/state are available.
|
||
Due to this, clients SHOULD NOT form ENRs and begin peer discovery until genesis values are known.
|
||
One notable exception to this rule is the distribution of bootnode ENRs prior to genesis.
|
||
In this case, bootnode ENRs SHOULD be initially distributed with `eth2` field set as
|
||
`ENRForkID(fork_digest=compute_fork_digest(GENESIS_FORK_VERSION, b'\x00'*32), next_fork_version=GENESIS_FORK_VERSION, next_fork_epoch=FAR_FUTURE_EPOCH)`.
|
||
After genesis values are known, the bootnodes SHOULD update ENRs to participate in normal discovery operations.
|
||
|
||
Clients SHOULD connect to peers with `fork_digest`, `next_fork_version`, and `next_fork_epoch` that match local values.
|
||
|
||
Clients MAY connect to peers with the same `fork_digest` but a different `next_fork_version`/`next_fork_epoch`.
|
||
Unless `ENRForkID` is manually updated to matching prior to the earlier `next_fork_epoch` of the two clients,
|
||
these connecting clients will be unable to successfully interact starting at the earlier `next_fork_epoch`.
|
||
|
||
#### General capabilities
|
||
|
||
ENRs MUST include a structure enumerating the capabilities offered by the peer in an efficient manner.
|
||
The concrete solution is currently undefined.
|
||
Proposals include using namespaced bloom filters mapping capabilities to specific protocol IDs supported under that capability.
|
||
|
||
### Topic advertisement
|
||
|
||
discv5's topic advertisement feature is not expected to be ready for mainnet launch of Phase 0.
|
||
|
||
Once this feature is built out and stable, we expect to use topic advertisement as a rendezvous facility for peers on shards.
|
||
Until then, the ENR [attestation subnet bitfield](#attestation-subnet-bitfield) will be used for discovery of peers on particular subnets.
|
||
|
||
# Design decision rationale
|
||
|
||
## Transport
|
||
|
||
### Why are we defining specific transports?
|
||
|
||
libp2p peers can listen on multiple transports concurrently, and these can change over time.
|
||
Multiaddrs encode not only the address but also the transport to be used to dial.
|
||
|
||
Due to this dynamic nature, agreeing on specific transports like TCP, QUIC, or WebSockets on paper becomes irrelevant.
|
||
|
||
However, it is useful to define a minimum baseline for interoperability purposes.
|
||
|
||
### Can clients support other transports/handshakes than the ones mandated by the spec?
|
||
|
||
Clients may support other transports such as libp2p QUIC, WebSockets, and WebRTC transports, if available in the language of choice.
|
||
While interoperability shall not be harmed by lack of such support, the advantages are desirable:
|
||
|
||
- Better latency, performance, and other QoS characteristics (QUIC).
|
||
- Paving the way for interfacing with future light clients (WebSockets, WebRTC).
|
||
|
||
The libp2p QUIC transport inherently relies on TLS 1.3 per requirement in section 7
|
||
of the [QUIC protocol specification](https://tools.ietf.org/html/draft-ietf-quic-transport-22#section-7)
|
||
and the accompanying [QUIC-TLS document](https://tools.ietf.org/html/draft-ietf-quic-tls-22).
|
||
|
||
The usage of one handshake procedure or the other shall be transparent to the Eth2 application layer,
|
||
once the libp2p Host/Node object has been configured appropriately.
|
||
|
||
### What are the advantages of using TCP/QUIC/Websockets?
|
||
|
||
TCP is a reliable, ordered, full-duplex, congestion-controlled network protocol that powers much of the Internet as we know it today.
|
||
HTTP/1.1 and HTTP/2 run atop TCP.
|
||
|
||
QUIC is a new protocol that’s in the final stages of specification by the IETF QUIC WG.
|
||
It emerged from Google’s SPDY experiment. The QUIC transport is undoubtedly promising.
|
||
It’s UDP-based yet reliable, ordered, multiplexed, natively secure (TLS 1.3), reduces latency vs. TCP,
|
||
and offers stream-level and connection-level congestion control (thus removing head-of-line blocking),
|
||
0-RTT connection establishment, and endpoint migration, amongst other features.
|
||
UDP also has better NAT traversal properties than TCP—something we desperately pursue in peer-to-peer networks.
|
||
|
||
QUIC is being adopted as the underlying protocol for HTTP/3.
|
||
This has the potential to award us censorship resistance via deep packet inspection for free.
|
||
Provided that we use the same port numbers and encryption mechanisms as HTTP/3, our traffic may be indistinguishable from standard web traffic,
|
||
and we may only become subject to standard IP-based firewall filtering—something we can counteract via other mechanisms.
|
||
|
||
WebSockets and/or WebRTC transports are necessary for interaction with browsers,
|
||
and will become increasingly important as we incorporate browser-based light clients to the Eth2 network.
|
||
|
||
### Why do we not just support a single transport?
|
||
|
||
Networks evolve.
|
||
Hardcoding design decisions leads to ossification, preventing the evolution of networks alongside the state of the art.
|
||
Introducing changes on an ossified protocol is very costly, and sometimes, downright impracticable without causing undesirable breakage.
|
||
|
||
Modeling for upgradeability and dynamic transport selection from the get-go lays the foundation for a future-proof stack.
|
||
|
||
Clients can adopt new transports without breaking old ones, and the multi-transport ability enables constrained and sandboxed environments
|
||
(e.g. browsers, embedded devices) to interact with the network as first-class citizens via suitable/native transports (e.g. WSS),
|
||
without the need for proxying or trust delegation to servers.
|
||
|
||
### Why are we not using QUIC from the start?
|
||
|
||
The QUIC standard is still not finalized (at working draft 22 at the time of writing),
|
||
and not all mainstream runtimes/languages have mature, standard, and/or fully-interoperable [QUIC support](https://github.com/quicwg/base-drafts/wiki/Implementations).
|
||
One remarkable example is node.js, where the QUIC implementation is [in early development](https://github.com/nodejs/quic).
|
||
|
||
*Note*: [TLS 1.3 is a prerequisite of the QUIC transport](https://tools.ietf.org/html/draft-ietf-quic-transport-22#section-7),
|
||
although an experiment exists to integrate Noise as the QUIC crypto layer: [nQUIC](https://eprint.iacr.org/2019/028).
|
||
|
||
On the other hand, TLS 1.3 is the newest, simplified iteration of TLS.
|
||
Old, insecure, obsolete ciphers and algorithms have been removed, adopting Ed25519 as the sole ECDH key agreement function.
|
||
Handshakes are faster, 1-RTT data is supported, and session resumption is a reality, amongst other features.
|
||
|
||
## Multiplexing
|
||
|
||
### Why are we using mplex/yamux?
|
||
|
||
[Yamux](https://github.com/hashicorp/yamux/blob/master/spec.md) is a multiplexer invented by Hashicorp that supports stream-level congestion control.
|
||
Implementations exist in a limited set of languages, and it’s not a trivial piece to develop.
|
||
|
||
Conscious of that, the libp2p community conceptualized [mplex](https://github.com/libp2p/specs/blob/master/mplex/README.md)
|
||
as a simple, minimal multiplexer for usage with libp2p.
|
||
It does not support stream-level congestion control and is subject to head-of-line blocking.
|
||
|
||
Overlay multiplexers are not necessary with QUIC since the protocol provides native multiplexing,
|
||
but they need to be layered atop TCP, WebSockets, and other transports that lack such support.
|
||
|
||
## Protocol Negotiation
|
||
|
||
### When is multiselect 2.0 due and why do we plan to migrate to it?
|
||
|
||
multiselect 2.0 is currently being conceptualized.
|
||
The debate started [on this issue](https://github.com/libp2p/specs/pull/95),
|
||
but it got overloaded—as it tends to happen with large conceptual OSS discussions that touch the heart and core of a system.
|
||
|
||
At some point in 2020, we expect a renewed initiative to first define the requirements, constraints, assumptions, and features,
|
||
in order to lock in basic consensus upfront and subsequently build on that consensus by submitting a specification for implementation.
|
||
|
||
We plan to eventually migrate to multiselect 2.0 because it will:
|
||
|
||
1. Reduce round trips during connection bootstrapping and stream protocol negotiation.
|
||
2. Enable efficient one-stream-per-request interaction patterns.
|
||
3. Leverage *push data* mechanisms of underlying protocols to expedite negotiation.
|
||
4. Provide the building blocks for enhanced censorship resistance.
|
||
|
||
### What is the difference between connection-level and stream-level protocol negotiation?
|
||
|
||
All libp2p connections must be authenticated, encrypted, and multiplexed.
|
||
Connections using network transports unsupportive of native authentication/encryption and multiplexing (e.g. TCP) need to undergo protocol negotiation to agree on a mutually supported:
|
||
|
||
1. authentication/encryption mechanism (such as SecIO, TLS 1.3, Noise).
|
||
2. overlay multiplexer (such as mplex, Yamux, spdystream).
|
||
|
||
In this specification, we refer to these two as *connection-level negotiations*.
|
||
Transports supporting those features natively (such as QUIC) omit those negotiations.
|
||
|
||
After successfully selecting a multiplexer, all subsequent I/O happens over *streams*.
|
||
When opening streams, peers pin a protocol to that stream, by conducting *stream-level protocol negotiation*.
|
||
|
||
At present, multistream-select 1.0 is used for both types of negotiation,
|
||
but multiselect 2.0 will use dedicated mechanisms for connection bootstrapping process and stream protocol negotiation.
|
||
|
||
## Encryption
|
||
|
||
### Why are we not supporting SecIO?
|
||
|
||
SecIO has been the default encryption layer for libp2p for years.
|
||
It is used in IPFS and Filecoin. And although it will be superseded shortly, it is proven to work at scale.
|
||
|
||
Although SecIO has wide language support, we won’t be using it for mainnet because, amongst other things,
|
||
it requires several round trips to be sound, and doesn’t support early data (0-RTT data),
|
||
a mechanism that multiselect 2.0 will leverage to reduce round trips during connection bootstrapping.
|
||
|
||
SecIO is not considered secure for the purposes of this spec.
|
||
|
||
### Why are we using Noise?
|
||
|
||
Copied from the Noise Protocol Framework [website](http://www.noiseprotocol.org):
|
||
|
||
> Noise is a framework for building crypto protocols.
|
||
Noise protocols support mutual and optional authentication, identity hiding, forward secrecy, zero round-trip encryption, and other advanced features.
|
||
|
||
Noise in itself does not specify a single handshake procedure,
|
||
but provides a framework to build secure handshakes based on Diffie-Hellman key agreement with a variety of tradeoffs and guarantees.
|
||
|
||
Noise handshakes are lightweight and simple to understand,
|
||
and are used in major cryptographic-centric projects like WireGuard, I2P, and Lightning.
|
||
[Various](https://www.wireguard.com/papers/kobeissi-bhargavan-noise-explorer-2018.pdf) [studies](https://eprint.iacr.org/2019/436.pdf)
|
||
have assessed the stated security goals of several Noise handshakes with positive results.
|
||
|
||
### Why are we using encryption at all?
|
||
|
||
Transport level encryption secures message exchange and provides properties that are useful for privacy, safety, and censorship resistance.
|
||
These properties are derived from the following security guarantees that apply to the entire communication between two peers:
|
||
|
||
- Peer authentication: the peer I’m talking to is really who they claim to be and who I expect them to be.
|
||
- Confidentiality: no observer can eavesdrop on the content of our messages.
|
||
- Integrity: the data has not been tampered with by a third-party while in transit.
|
||
- Non-repudiation: the originating peer cannot dispute that they sent the message.
|
||
- Depending on the chosen algorithms and mechanisms (e.g. continuous HMAC), we may obtain additional guarantees,
|
||
such as non-replayability (this byte could’ve only been sent *now;* e.g. by using continuous HMACs),
|
||
or perfect forward secrecy (in the case that a peer key is compromised, the content of a past conversation will not be compromised).
|
||
|
||
Note that transport-level encryption is not exclusive of application-level encryption or cryptography.
|
||
Transport-level encryption secures the communication itself,
|
||
while application-level cryptography is necessary for the application’s use cases (e.g. signatures, randomness, etc.).
|
||
|
||
## Gossipsub
|
||
|
||
### Why are we using a pub/sub algorithm for block and attestation propagation?
|
||
|
||
Pubsub is a technique to broadcast/disseminate data across a network rapidly.
|
||
Such data is packaged in fire-and-forget messages that do not require a response from every recipient.
|
||
Peers subscribed to a topic participate in the propagation of messages in that topic.
|
||
|
||
The alternative is to maintain a fully connected mesh (all peers connected to each other 1:1), which scales poorly (O(n^2)).
|
||
|
||
### Why are we using topics to segregate encodings, yet only support one encoding?
|
||
|
||
For future extensibility with almost zero overhead now (besides the extra bytes in the topic name).
|
||
|
||
### How do we upgrade gossip channels (e.g. changes in encoding, compression)?
|
||
|
||
Changing gossipsub/broadcasts requires a coordinated upgrade where all clients start publishing to the new topic together, during a hard fork.
|
||
|
||
When a node is preparing for upcoming tasks (e.g. validator duty lookahead) on a gossipsub topic,
|
||
the node should join the topic of the future epoch in which the task is to occur in addition to listening to the topics for the current epoch.
|
||
|
||
### Why must all clients use the same gossip topic instead of one negotiated between each peer pair?
|
||
|
||
Supporting multiple topics/encodings would require the presence of relayers to translate between encodings
|
||
and topics so as to avoid network fragmentation where participants have diverging views on the gossiped state,
|
||
making the protocol more complicated and fragile.
|
||
|
||
Gossip protocols typically remember what messages they've seen for a finite period of time-based on message identity
|
||
-- if you publish the same message again after that time has passed,
|
||
it will be re-broadcast—adding a relay delay also makes this scenario more likely.
|
||
|
||
One can imagine that in a complicated upgrade scenario, we might have peers publishing the same message on two topics/encodings,
|
||
but the price here is pretty high in terms of overhead -- both computational and networking -- so we'd rather avoid that.
|
||
|
||
It is permitted for clients to publish data on alternative topics as long as they also publish on the network-wide mandatory topic.
|
||
|
||
### Why are the topics strings and not hashes?
|
||
|
||
Topic names have a hierarchical structure.
|
||
In the future, gossipsub may support wildcard subscriptions
|
||
(e.g. subscribe to all children topics under a root prefix) by way of prefix matching.
|
||
Enforcing hashes for topic names would preclude us from leveraging such features going forward.
|
||
|
||
No security or privacy guarantees are lost as a result of choosing plaintext topic names,
|
||
since the domain is finite anyway, and calculating a digest's preimage would be trivial.
|
||
|
||
Furthermore, the Eth2 topic names are shorter than their digest equivalents (assuming SHA-256 hash),
|
||
so hashing topics would bloat messages unnecessarily.
|
||
|
||
### Why are we overriding the default libp2p pubsub `message-id`?
|
||
|
||
For our current purposes, there is no need to address messages based on source peer,
|
||
and it seems likely we might even override the message `from` to obfuscate the peer.
|
||
By overriding the default `message-id` to use content-addressing we can filter unnecessary duplicates before hitting the application layer.
|
||
|
||
Some examples of where messages could be duplicated:
|
||
|
||
* A validator client connected to multiple beacon nodes publishing duplicate gossip messages
|
||
* Attestation aggregation strategies where clients partially aggregate attestations and propagate them.
|
||
Partial aggregates could be duplicated
|
||
* Clients re-publishing seen messages
|
||
|
||
### Why are these specific gossip parameters chosen?
|
||
|
||
- `D`, `D_low`, `D_high`, `D_lazy`: recommended defaults.
|
||
- `heartbeat_interval`: 0.7 seconds, recommended for eth2 in the [GossipSub evaluation report by Protocol Labs](https://gateway.ipfs.io/ipfs/QmRAFP5DBnvNjdYSbWhEhVRJJDFCLpPyvew5GwCCB4VxM4).
|
||
- `fanout_ttl`: 60 seconds, recommended default.
|
||
Fanout is primarily used by committees publishing attestations to subnets.
|
||
This happens once per epoch per validator and the subnet changes each epoch
|
||
so there is little to gain in having a `fanout_ttl` be increased from the recommended default.
|
||
- `mcache_len`: 6, increase by one to ensure that mcache is around for long
|
||
enough for `IWANT`s to respond to `IHAVE`s in the context of the shorter
|
||
`heartbeat_interval`. If `mcache_gossip` is increased, this param should be
|
||
increased to be at least `3` (~2 seconds) more than `mcache_gossip`.
|
||
- `mcache_gossip`: 3, recommended default. This can be increased to 5 or 6
|
||
(~4 seconds) if gossip times are longer than expected and the current window
|
||
does not provide enough responsiveness during adverse conditions.
|
||
- `seen_ttl`: `SLOTS_PER_EPOCH * SECONDS_PER_SLOT / heartbeat_interval = approx. 550`.
|
||
Attestation gossip validity is bounded by an epoch, so this is the safe max bound.
|
||
|
||
|
||
### Why is there `MAXIMUM_GOSSIP_CLOCK_DISPARITY` when validating slot ranges of messages in gossip subnets?
|
||
|
||
For some gossip channels (e.g. those for Attestations and BeaconBlocks),
|
||
there are designated ranges of slots during which particular messages can be sent,
|
||
limiting messages gossiped to those that can be reasonably used in the consensus at the current time/slot.
|
||
This is to reduce optionality in DoS attacks.
|
||
|
||
`MAXIMUM_GOSSIP_CLOCK_DISPARITY` provides some leeway in validating slot ranges to prevent the gossip network
|
||
from becoming overly brittle with respect to clock disparity.
|
||
For minimum and maximum allowable slot broadcast times,
|
||
`MAXIMUM_GOSSIP_CLOCK_DISPARITY` MUST be subtracted and added respectively, marginally extending the valid range.
|
||
Although messages can at times be eagerly gossiped to the network,
|
||
the node's fork choice prevents integration of these messages into the actual consensus until the _actual local start_ of the designated slot.
|
||
|
||
The value of this constant is currently a placeholder and will be tuned based on data observed in testnets.
|
||
|
||
### Why are there `ATTESTATION_SUBNET_COUNT` attestation subnets?
|
||
|
||
Depending on the number of validators, it may be more efficient to group shard subnets and might provide better stability for the gossipsub channel.
|
||
The exact grouping will be dependent on more involved network tests.
|
||
This constant allows for more flexibility in setting up the network topology for attestation aggregation (as aggregation should happen on each subnet).
|
||
The value is currently set to to be equal `MAX_COMMITTEES_PER_SLOT` if/until network tests indicate otherwise.
|
||
|
||
### Why are attestations limited to be broadcast on gossip channels within `SLOTS_PER_EPOCH` slots?
|
||
|
||
Attestations can only be included on chain within an epoch's worth of slots so this is the natural cutoff.
|
||
There is no utility to the chain to broadcast attestations older than one epoch,
|
||
and because validators have a chance to make a new attestation each epoch,
|
||
there is minimal utility to the fork choice to relay old attestations as a new latest message can soon be created by each validator.
|
||
|
||
In addition to this, relaying attestations requires validating the attestation in the context of the `state` during which it was created.
|
||
Thus, validating arbitrarily old attestations would put additional requirements on which states need to be readily available to the node.
|
||
This would result in a higher resource burden and could serve as a DoS vector.
|
||
|
||
### Why are aggregate attestations broadcast to the global topic as `AggregateAndProof`s rather than just as `Attestation`s?
|
||
|
||
The dominant strategy for an individual validator is to always broadcast an aggregate containing their own attestation
|
||
to the global channel to ensure that proposers see their attestation for inclusion.
|
||
Using a private selection criteria and providing this proof of selection alongside
|
||
the gossiped aggregate ensures that this dominant strategy will not flood the global channel.
|
||
|
||
Also, an attacker can create any number of honest-looking aggregates and broadcast them to the global pubsub channel.
|
||
Thus without some sort of proof of selection as an aggregator, the global channel can trivially be spammed.
|
||
|
||
### Why are we sending entire objects in the pubsub and not just hashes?
|
||
|
||
Entire objects should be sent to get the greatest propagation speeds.
|
||
If only hashes are sent, then block and attestation propagation is dependent on recursive requests from each peer.
|
||
In a hash-only scenario, peers could receive hashes without knowing who to download the actual contents from.
|
||
Sending entire objects ensures that they get propagated through the entire network.
|
||
|
||
### Should clients gossip blocks if they *cannot* validate the proposer signature due to not yet being synced, not knowing the head block, etc?
|
||
|
||
The prohibition of unverified-block-gossiping extends to nodes that cannot verify a signature
|
||
due to not being fully synced to ensure that such (amplified) DOS attacks are not possible.
|
||
|
||
### How are we going to discover peers in a gossipsub topic?
|
||
|
||
In Phase 0, peers for attestation subnets will be found using the `attnets` entry in the ENR.
|
||
|
||
Although this method will be sufficient for early phases of Eth2, we aim to use the more appropriate discv5 topics for this and other similar tasks in the future.
|
||
ENRs should ultimately not be used for this purpose.
|
||
They are best suited to store identity, location, and capability information, rather than more volatile advertisements.
|
||
|
||
### How should fork version be used in practice?
|
||
|
||
Fork versions are to be manually updated (likely via incrementing) at each hard fork.
|
||
This is to provide native domain separation for signatures as well as to aid in usefulness for identitying peers (via ENRs)
|
||
and versioning network protocols (e.g. using fork version to naturally version gossipsub topics).
|
||
|
||
`BeaconState.genesis_validators_root` is mixed into signature and ENR fork domains (`ForkDigest`) to aid in the ease of domain separation between chains.
|
||
This allows fork versions to safely be reused across chains except for the case of contentious forks using the same genesis.
|
||
In these cases, extra care should be taken to isolate fork versions (e.g. flip a high order bit in all future versions of one of the chains).
|
||
|
||
A node locally stores all previous and future planned fork versions along with the each fork epoch.
|
||
This allows for handling sync and processing messages starting from past forks/epochs.
|
||
|
||
## Req/Resp
|
||
|
||
### Why segregate requests into dedicated protocol IDs?
|
||
|
||
Requests are segregated by protocol ID to:
|
||
|
||
1. Leverage protocol routing in libp2p, such that the libp2p stack will route the incoming stream to the appropriate handler.
|
||
This allows the handler function for each request type to be self-contained.
|
||
For an analogy, think about how you attach HTTP handlers to a REST API server.
|
||
2. Version requests independently.
|
||
In a coarser-grained umbrella protocol, the entire protocol would have to be versioned even if just one field in a single message changed.
|
||
3. Enable clients to select the individual requests/versions they support.
|
||
It would no longer be a strict requirement to support all requests,
|
||
and clients, in principle, could support a subset of requests and variety of versions.
|
||
4. Enable flexibility and agility for clients adopting spec changes that impact the request, by signalling to peers exactly which subset of new/old requests they support.
|
||
5. Enable clients to explicitly choose backwards compatibility at the request granularity.
|
||
Without this, clients would be forced to support entire versions of the coarser request protocol.
|
||
6. Parallelise RFCs (or Eth2 EIPs).
|
||
By decoupling requests from one another, each RFC that affects the request protocol can be deployed/tested/debated independently
|
||
without relying on a synchronization point to version the general top-level protocol.
|
||
1. This has the benefit that clients can explicitly choose which RFCs to deploy
|
||
without buying into all other RFCs that may be included in that top-level version.
|
||
2. Affording this level of granularity with a top-level protocol would imply creating as many variants
|
||
(e.g. /protocol/43-{a,b,c,d,...}) as the cartesian product of RFCs inflight, O(n^2).
|
||
7. Allow us to simplify the payload of requests.
|
||
Request-id’s and method-ids no longer need to be sent.
|
||
The encoding/request type and version can all be handled by the framework.
|
||
|
||
**Caveat**: The protocol negotiation component in the current version of libp2p is called multistream-select 1.0.
|
||
It is somewhat naïve and introduces overhead on every request when negotiating streams,
|
||
although implementation-specific optimizations are possible to save this cost.
|
||
Multiselect 2.0 will eventually remove this overhead by memoizing previously selected protocols, and modeling shared protocol tables.
|
||
Fortunately, this req/resp protocol is not the expected network bottleneck in the protocol
|
||
so the additional overhead is not expected to significantly hinder this domain.
|
||
|
||
### Why are messages length-prefixed with a protobuf varint in the SSZ-encoding?
|
||
|
||
We are using single-use streams where each stream is closed at the end of the message.
|
||
Thus, libp2p transparently handles message delimiting in the underlying stream.
|
||
libp2p streams are full-duplex, and each party is responsible for closing their write side (like in TCP).
|
||
We can therefore use stream closure to mark the end of the request and response independently.
|
||
|
||
Nevertheless, in the case of `ssz_snappy`, messages are still length-prefixed with the length of the underlying data:
|
||
* A basic reader can prepare a correctly sized buffer before reading the message
|
||
* A more advanced reader can stream-decode SSZ given the length of the SSZ data.
|
||
* Alignment with protocols like gRPC over HTTP/2 that prefix with length
|
||
* Sanity checking of message length, and enabling much stricter message length limiting based on SSZ type information,
|
||
to provide even more DOS protection than the global message length already does.
|
||
E.g. a small `Status` message does not nearly require `MAX_CHUNK_SIZE` bytes.
|
||
|
||
[Protobuf varint](https://developers.google.com/protocol-buffers/docs/encoding#varints) is an efficient technique to encode variable-length (unsigned here) ints.
|
||
Instead of reserving a fixed-size field of as many bytes as necessary to convey the maximum possible value, this field is elastic in exchange for 1-bit overhead per byte.
|
||
|
||
### Why do we version protocol strings with ordinals instead of semver?
|
||
|
||
Using semver for network protocols is confusing.
|
||
It is never clear what a change in a field, even if backwards compatible on deserialization, actually implies.
|
||
Network protocol agreement should be explicit. Imagine two peers:
|
||
|
||
- Peer A supporting v1.1.1 of protocol X.
|
||
- Peer B supporting v1.1.2 of protocol X.
|
||
|
||
These two peers should never speak to each other because the results can be unpredictable.
|
||
This is an oversimplification: imagine the same problem with a set of 10 possible versions.
|
||
We now have 10^2 (100) possible outcomes that peers need to model for. The resulting complexity is unwieldy.
|
||
|
||
For this reason, we rely on negotiation of explicit, verbatim protocols.
|
||
In the above case, peer B would provide backwards compatibility by supporting and advertising both v1.1.1 and v1.1.2 of the protocol.
|
||
|
||
Therefore, semver would be relegated to convey expectations at the human level, and it wouldn't do a good job there either,
|
||
because it's unclear if "backwards compatibility" and "breaking change" apply only to wire schema level, to behavior, etc.
|
||
|
||
For this reason, we remove and replace semver with ordinals that require explicit agreement and do not mandate a specific policy for changes.
|
||
|
||
### Why is it called Req/Resp and not RPC?
|
||
|
||
Req/Resp is used to avoid confusion with JSON-RPC and similar user-client interaction mechanisms.
|
||
|
||
### Why do we allow empty responses in block requests?
|
||
|
||
When requesting blocks by range or root, it may happen that there are no blocks in the selected range or the responding node does not have the requested blocks.
|
||
|
||
Thus, it may happen that we need to transmit an empty list - there are several ways to encode this:
|
||
|
||
0) Close the stream without sending any data
|
||
1) Add a `null` option to the `success` response, for example by introducing an additional byte
|
||
2) Respond with an error result, using a specific error code for "No data"
|
||
|
||
Semantically, it is not an error that a block is missing during a slot making option 2 unnatural.
|
||
|
||
Option 1 allows allows the responder to signal "no block", but this information may be wrong - for example in the case of a malicious node.
|
||
|
||
Under option 0, there is no way for a client to distinguish between a slot without a block and an incomplete response,
|
||
but given that it already must contain logic to handle the uncertainty of a malicious peer, option 0 was chosen.
|
||
Clients should mark any slots missing blocks as unknown until they can be verified as not containing a block by successive blocks.
|
||
|
||
Assuming option 0 with no special `null` encoding, consider a request for slots `2, 3, 4`
|
||
-- if there was no block produced at slot 4, the response would be `2, 3, EOF`.
|
||
Now consider the same situation, but where only `4` is requested
|
||
-- closing the stream with only `EOF` (without any `response_chunk`) is consistent.
|
||
|
||
Failing to provide blocks that nodes "should" have is reason to trust a peer less
|
||
-- for example, if a particular peer gossips a block, it should have access to its parent.
|
||
If a request for the parent fails, it's indicative of poor peer quality since peers should validate blocks before gossiping them.
|
||
|
||
### Why does `BeaconBlocksByRange` let the server choose which branch to send blocks from?
|
||
|
||
When connecting, the `Status` message gives an idea about the sync status of a particular peer, but this changes over time.
|
||
By the time a subsequent `BeaconBlockByRange` request is processed, the information may be stale,
|
||
and the responding side might have moved on to a new finalization point and pruned blocks around the previous head and finalized blocks.
|
||
|
||
To avoid this race condition, we allow the responding side to choose which branch to send to the requesting client.
|
||
The requesting client then goes on to validate the blocks and incorporate them in their own database
|
||
-- because they follow the same rules, they should at this point arrive at the same canonical chain.
|
||
|
||
### What's the effect of empty slots on the sync algorithm?
|
||
|
||
When syncing one can only tell that a slot has been skipped on a particular branch
|
||
by examining subsequent blocks and analyzing the graph formed by the parent root.
|
||
Because the server side may choose to omit blocks in the response for any reason, clients must validate the graph and be prepared to fill in gaps.
|
||
|
||
For example, if a peer responds with blocks [2, 3] when asked for [2, 3, 4], clients may not assume that block 4 doesn't exist
|
||
-- it merely means that the responding peer did not send it (they may not have it yet or may maliciously be trying to hide it)
|
||
and successive blocks will be needed to determine if there exists a block at slot 4 in this particular branch.
|
||
|
||
## Discovery
|
||
|
||
### Why are we using discv5 and not libp2p Kademlia DHT?
|
||
|
||
discv5 is a standalone protocol, running on UDP on a dedicated port, meant for peer and service discovery only.
|
||
discv5 supports self-certified, flexible peer records (ENRs) and topic-based advertisement, both of which are, or will be, requirements in this context.
|
||
|
||
On the other hand, libp2p Kademlia DHT is a fully-fledged DHT protocol/implementations
|
||
with content routing and storage capabilities, both of which are irrelevant in this context.
|
||
|
||
We assume that Eth 1.0 nodes will evolve to support discv5.
|
||
By sharing the discovery network between Eth 1.0 and 2.0,
|
||
we benefit from the additive effect on network size that enhances resilience and resistance against certain attacks,
|
||
to which smaller networks are more vulnerable.
|
||
It should also help light clients of both networks find nodes with specific capabilities.
|
||
|
||
discv5 is in the process of being audited.
|
||
|
||
### What is the difference between an ENR and a multiaddr, and why are we using ENRs?
|
||
|
||
Ethereum Node Records are self-certified node records.
|
||
Nodes craft and disseminate ENRs for themselves, proving authorship via a cryptographic signature.
|
||
ENRs are sequentially indexed, enabling conflicts to be resolved.
|
||
|
||
ENRs are key-value records with string-indexed ASCII keys.
|
||
They can store arbitrary information, but EIP-778 specifies a pre-defined dictionary, including IPv4 and IPv6 addresses, secp256k1 public keys, etc.
|
||
|
||
Comparing ENRs and multiaddrs is like comparing apples and oranges.
|
||
ENRs are self-certified containers of identity, addresses, and metadata about a node.
|
||
Multiaddrs are address strings with the peculiarity that they’re self-describing, composable and future-proof.
|
||
An ENR can contain multiaddrs, and multiaddrs can be derived securely from the fields of an authenticated ENR.
|
||
|
||
discv5 uses ENRs and we will presumably need to:
|
||
|
||
1. Add `multiaddr` to the dictionary, so that nodes can advertise their multiaddr under a reserved namespace in ENRs. – and/or –
|
||
2. Define a bi-directional conversion function between multiaddrs and the corresponding denormalized fields in an ENR
|
||
(ip, ip6, tcp, tcp6, etc.), for compatibility with nodes that do not support multiaddr natively (e.g. Eth 1.0 nodes).
|
||
|
||
### Why do we not form ENRs and find peers until genesis block/state is known?
|
||
|
||
Although client software might very well be running locally prior to the solidification of the eth2 genesis state and block,
|
||
clients cannot form valid ENRs prior to this point.
|
||
ENRs contain `fork_digest` which utilizes the `genesis_validators_root` for a cleaner separation between chains
|
||
so prior to knowing genesis, we cannot use `fork_digest` to cleanly find peers on our intended chain.
|
||
Once genesis data is known, we can then form ENRs and safely find peers.
|
||
|
||
When using an eth1 deposit contract for deposits, `fork_digest` will be known `GENESIS_DELAY` (48hours in mainnet configuration) before `genesis_time`,
|
||
providing ample time to find peers and form initial connections and gossip subnets prior to genesis.
|
||
|
||
## Compression/Encoding
|
||
|
||
### Why are we using SSZ for encoding?
|
||
|
||
SSZ is used at the consensus layer, and all implementations should have support for SSZ-encoding/decoding,
|
||
requiring no further dependencies to be added to client implementations.
|
||
This is a natural choice for serializing objects to be sent across the wire.
|
||
The actual data in most protocols will be further compressed for efficiency.
|
||
|
||
SSZ has well-defined schemas for consensus objects (typically sent across the wire) reducing any serialization schema data that needs to be sent.
|
||
It also has defined all required types that are required for this network specification.
|
||
|
||
### Why are we compressing, and at which layers?
|
||
|
||
We compress on the wire to achieve smaller payloads per-message, which, in aggregate,
|
||
result in higher efficiency, better utilization of available bandwidth, and overall reduction in network-wide traffic overhead.
|
||
|
||
At this time, libp2p does not have an out-of-the-box compression feature that can be dynamically negotiated
|
||
and layered atop connections and streams, but it is [being considered](https://github.com/libp2p/libp2p/issues/81).
|
||
|
||
This is a non-trivial feature because the behavior
|
||
of network IO loops, kernel buffers, chunking, and packet fragmentation, amongst others, need to be taken into account.
|
||
libp2p streams are unbounded streams, whereas compression algorithms work best on bounded byte streams of which we have some prior knowledge.
|
||
|
||
Compression tends not to be a one-size-fits-all problem.
|
||
A lot of variables need careful evaluation, and generic approaches/choices lead to poor size shavings,
|
||
which may even be counterproductive when factoring in the CPU and memory tradeoff.
|
||
|
||
For all these reasons, generically negotiating compression algorithms may be treated as a research problem at the libp2p community,
|
||
one we’re happy to tackle in the medium-term.
|
||
|
||
At this stage, the wisest choice is to consider libp2p a messenger of bytes,
|
||
and to make application layer participate in compressing those bytes.
|
||
This looks different depending on the interaction layer:
|
||
|
||
- Gossip domain: since gossipsub has a framing protocol and exposes an API, we compress the payload
|
||
(when dictated by the encoding token in the topic name) prior to publishing the message via the API.
|
||
No length-prefixing is necessary because protobuf takes care of bounding the field in the serialized form.
|
||
- Req/Resp domain: since we define custom protocols that operate on byte streams,
|
||
implementers are encouraged to encapsulate the encoding and compression logic behind
|
||
MessageReader and MessageWriter components/strategies that can be layered on top of the raw byte streams.
|
||
|
||
### Why are using Snappy for compression?
|
||
|
||
Snappy is used in Ethereum 1.0. It is well maintained by Google, has good benchmarks,
|
||
and can calculate the size of the uncompressed object without inflating it in memory.
|
||
This prevents DOS vectors where large uncompressed data is sent.
|
||
|
||
### Can I get access to unencrypted bytes on the wire for debugging purposes?
|
||
|
||
Yes, you can add loggers in your libp2p protocol handlers to log incoming and outgoing messages.
|
||
It is recommended to use programming design patterns to encapsulate the logging logic cleanly.
|
||
|
||
If your libp2p library relies on frameworks/runtimes such as Netty (jvm) or Node.js (javascript),
|
||
you can use logging facilities in those frameworks/runtimes to enable message tracing.
|
||
|
||
For specific ad-hoc testing scenarios, you can use the [plaintext/2.0.0 secure channel](https://github.com/libp2p/specs/blob/master/plaintext/README.md)
|
||
(which is essentially no-op encryption or message authentication), in combination with tcpdump or Wireshark to inspect the wire.
|
||
|
||
### What are SSZ type size bounds?
|
||
|
||
The SSZ encoding outputs of each type have size bounds: each dynamic type, such as a list, has a "limit", which can be used to compute the maximum valid output size.
|
||
Note that for some more complex dynamic-length objects, element offsets (4 bytes each) may need to be included.
|
||
Other types are static, they have a fixed size: no dynamic-length content is involved, and the minimum and maximum bounds are the same.
|
||
|
||
For reference, the type bounds can be computed ahead of time, [as per this example](https://gist.github.com/protolambda/db75c7faa1e94f2464787a480e5d613e).
|
||
It is advisable to derive these lengths from the SSZ type definitions in use, to ensure that version changes do not cause out-of-sync type bounds.
|
||
|
||
# libp2p implementations matrix
|
||
|
||
This section will soon contain a matrix showing the maturity/state of the libp2p features required
|
||
by this spec across the languages in which Eth2 clients are being developed.
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