forked from DecentralizedClimateFoundation/DCIPs
173 lines
8.4 KiB
Markdown
173 lines
8.4 KiB
Markdown
---
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eip: 1459
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title: Node Discovery via DNS
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description: Scheme for authenticated updateable Ethereum node lists via DNS.
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author: Felix Lange (@fjl), Péter Szilágyi (@karalabe)
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discussions-to: https://github.com/ethereum/devp2p/issues/50
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status: Draft
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type: Standards Track
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category: Networking
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created: 2018-09-26
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requires: 778
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---
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## Abstract
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This document describes a scheme for authenticated, updateable Ethereum node
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lists retrievable via DNS.
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## Motivation
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Many Ethereum clients contain hard-coded bootstrap node lists. Updating those
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lists requires a software update. The current lists are small, giving the client
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little choice of initial entry point into the Ethereum network. We would like to
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maintain larger node lists containing hundreds of nodes, and update them
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regularly.
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The scheme described here is a replacement for client bootstrap node lists with
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equivalent security and many additional benefits. Large lists populated by
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traversing the node discovery DHT can serve as a fallback option for nodes which
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can't join the DHT due to restrictive network policy. DNS-based node lists may
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also be useful to Ethereum peering providers because their customers can
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configure the client to use the provider's list.
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## Specification
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A 'node list' is a list of 'node records' [as defined by EIP-778](./eip-778.md)
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of arbitrary length. Lists
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may refer to other lists using links. The entire list is signed using a
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secp256k1 private key. The corresponding public key must be known to the client
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in order to verify the list.
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To refer to a DNS node list, clients use a URL with 'enrtree' scheme. The URL
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contains the DNS name on which the list can be found as well as the public key
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that signed the list. The public key is contained in the username part of the
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URL and is the base32 encoding (RFC-4648) of the compressed 32-byte binary public key.
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Example:
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enrtree://AM5FCQLWIZX2QFPNJAP7VUERCCRNGRHWZG3YYHIUV7BVDQ5FDPRT2@nodes.example.org
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This URL refers to a node list at the DNS name 'nodes.example.org' and is signed
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by the public key
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`0x049f88229042fef9200246f49f94d9b77c4e954721442714e85850cb6d9e5daf2d880ea0e53cb3ac1a75f9923c2726a4f941f7d326781baa6380754a360de5c2b6`
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### DNS Record Structure
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The nodes in a list are encoded as a merkle tree for distribution via the DNS
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protocol. Entries of the merkle tree are contained in DNS TXT records. The root
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of the tree is a TXT record with the following content:
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enrtree-root:v1 e=<enr-root> l=<link-root> seq=<sequence-number> sig=<signature>
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where
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- `enr-root` and `link-root` refer to the root hashes of subtrees containing
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nodes and links subtrees.
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- `sequence-number` is the tree's update sequence number, a decimal integer.
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- `signature` is a 65-byte secp256k1 EC signature over the keccak256 hash of the
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record content, excluding the `sig=` part, encoded as URL-safe base64 (RFC-4648).
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Further TXT records on subdomains map hashes to one of three entry types. The
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subdomain name of any entry is the base32 encoding of the (abbreviated)
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keccak256 hash of its text content.
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- `enrtree-branch:<h₁>,<h₂>,...,<hₙ>` is an intermediate tree entry containing
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hashes of subtree entries.
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- `enrtree://<key>@<fqdn>` is a leaf pointing to a different list located at
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another fully qualified domain name. Note that this format matches the URL
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encoding. This type of entry may only appear in the subtree pointed to by
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`link-root`.
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- `enr:<node-record>` is a leaf containing a node record. The node record is
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encoded as a URL-safe base64 string. Note that this type of entry matches the
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canonical ENR text encoding. It may only appear in the `enr-root` subtree.
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No particular ordering or structure is defined for the tree. Whenever the tree
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is updated, its sequence number should increase. The content of any TXT record
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should be small enough to fit into the 512 byte limit imposed on UDP DNS
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packets. This limits the number of hashes that can be placed into an
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`enrtree-branch` entry.
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Example in zone file format:
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; name ttl class type content
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@ 60 IN TXT enrtree-root:v1 e=JWXYDBPXYWG6FX3GMDIBFA6CJ4 l=C7HRFPF3BLGF3YR4DY5KX3SMBE seq=1 sig=o908WmNp7LibOfPsr4btQwatZJ5URBr2ZAuxvK4UWHlsB9sUOTJQaGAlLPVAhM__XJesCHxLISo94z5Z2a463gA
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C7HRFPF3BLGF3YR4DY5KX3SMBE 86900 IN TXT enrtree://AM5FCQLWIZX2QFPNJAP7VUERCCRNGRHWZG3YYHIUV7BVDQ5FDPRT2@morenodes.example.org
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JWXYDBPXYWG6FX3GMDIBFA6CJ4 86900 IN TXT enrtree-branch:2XS2367YHAXJFGLZHVAWLQD4ZY,H4FHT4B454P6UXFD7JCYQ5PWDY,MHTDO6TMUBRIA2XWG5LUDACK24
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2XS2367YHAXJFGLZHVAWLQD4ZY 86900 IN TXT enr:-HW4QOFzoVLaFJnNhbgMoDXPnOvcdVuj7pDpqRvh6BRDO68aVi5ZcjB3vzQRZH2IcLBGHzo8uUN3snqmgTiE56CH3AMBgmlkgnY0iXNlY3AyNTZrMaECC2_24YYkYHEgdzxlSNKQEnHhuNAbNlMlWJxrJxbAFvA
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H4FHT4B454P6UXFD7JCYQ5PWDY 86900 IN TXT enr:-HW4QAggRauloj2SDLtIHN1XBkvhFZ1vtf1raYQp9TBW2RD5EEawDzbtSmlXUfnaHcvwOizhVYLtr7e6vw7NAf6mTuoCgmlkgnY0iXNlY3AyNTZrMaECjrXI8TLNXU0f8cthpAMxEshUyQlK-AM0PW2wfrnacNI
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MHTDO6TMUBRIA2XWG5LUDACK24 86900 IN TXT enr:-HW4QLAYqmrwllBEnzWWs7I5Ev2IAs7x_dZlbYdRdMUx5EyKHDXp7AV5CkuPGUPdvbv1_Ms1CPfhcGCvSElSosZmyoqAgmlkgnY0iXNlY3AyNTZrMaECriawHKWdDRk2xeZkrOXBQ0dfMFLHY4eENZwdufn1S1o
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### Client Protocol
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To find nodes at a given DNS name, say "mynodes.org":
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1. Resolve the TXT record of the name and check whether it contains a valid
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"enrtree-root=v1" entry. Let's say the `enr-root` hash contained in the entry
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is "CFZUWDU7JNQR4VTCZVOJZ5ROV4".
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2. Verify the signature on the root against the known public key and check
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whether the sequence number is larger than or equal to any previous number
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seen for that name.
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3. Resolve the TXT record of the hash subdomain, e.g.
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"CFZUWDU7JNQR4VTCZVOJZ5ROV4.mynodes.org" and verify whether the content
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matches the hash.
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4. The next step depends on the entry type found:
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- for `enrtree-branch`: parse the list of hashes and continue resolving them (step 3).
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- for `enr`: decode, verify the node record and import it to local node storage.
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During traversal, the client must track hashes and domains which are already
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resolved to avoid going into an infinite loop. It's in the client's best
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interest to traverse the tree in random order.
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Client implementations should avoid downloading the entire tree at once during
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normal operation. It's much better to request entries via DNS when-needed, i.e.
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at the time when the client is looking for peers.
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## Rationale
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### Why DNS?
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We have chosen DNS as the distribution medium because it is always available,
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even under restrictive network conditions. The protocol provides low latency and
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answers to DNS queries can be cached by intermediate resolvers. No custom server
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software is needed. Node lists can be deployed to any DNS provider such as
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CloudFlare DNS, dnsimple, Amazon Route 53 using their respective client
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libraries.
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### Why is this a merkle tree?
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Being a merkle tree, any node list can be authenticated by a single signature on
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the root. Hash subdomains protect the integrity of the list. At worst
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intermediate resolvers can block access to the list or disallow updates to it,
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but cannot corrupt its content. The sequence number prevents replacing the root
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with an older version.
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Synchronizing updates on the client side can be done incrementally, which
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matters for large lists. Individual entries of the tree are small enough to fit
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into a single UDP packet, ensuring compatibility with environments where only
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basic UDP DNS is available. The tree format also works well with caching
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resolvers: only the root of the tree needs a short TTL. Intermediate entries and
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leaves can be cached for days.
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### Why does the link subtree exist?
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Links between lists enable federation and web-of-trust functionality. The
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operator of a large list can delegate maintenance to other list providers. If
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two node lists link to each other, users can use either list and get nodes from
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both.
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The link subtree is separate from the tree containing ENRs. This is done to
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enable client implementations to sync these trees independently. A client
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wanting to get as many nodes as possible will sync the link tree first and add
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all linked names to the sync horizon.
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## Security Considerations
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Discovery via DNS is less secure than via DHT, because it relies on a trusted
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party to publish the records regularly. The actor could easily eclipse
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bootstrapping nodes by only publishing node records that it controls.
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## Copyright
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Copyright and related rights waived via [CC0](../LICENSE.md).
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