This library is intended to use ethereum addresses or secp256k1 publicKeys as fully self-managed Decentralized Identifiers and wrap them in a DID Document
It supports the proposed Decentralized Identifiers spec from the W3C Credentials Community Group.
It requires the did-resolver
library, which is the primary interface for resolving DIDs.
This DID method relies on the ethr-did-registry.
To encode a DID for an Ethereum address on the ethereum mainnet, simply prepend did:moon:
eg:
did:moon:0xf3beac30c498d9e26865f34fcaa57dbb935b0d74
Multi-network DIDs are also supported, if the proper configuration is provided during setup.
For example:
did:moon:0x5:0xf3beac30c498d9e26865f34fcaa57dbb935b0d74
gets resolved on the goerli testnet (chainID=0x5), and
represents a distinct identifier than the generic one, with different DID documents and different key rotation history.
The did resolver takes the ethereum address, looks at contract events and builds a DID document based on the ERC1056
Events corresponding to the address. When an identifier is a full publicKey
, the corresponding ethereumAddress
is
computed and checked in the same manner.
The minimal DID document for an ethereum address 0xb9c5714089478a327f09197987f16f9e5d936e8a
with no transactions to
the registry looks like this:
{
"@context": ["https://www.w3.org/ns/did/v1", "https://w3id.org/security/suites/secp256k1recovery-2020/v2"],
"id": "did:moon:0xb9c5714089478a327f09197987f16f9e5d936e8a",
"verificationMethod": [
{
"id": "did:moon:0xb9c5714089478a327f09197987f16f9e5d936e8a#controller",
"type": "EcdsaSecp256k1RecoveryMethod2020",
"controller": "did:moon:0xb9c5714089478a327f09197987f16f9e5d936e8a",
"blockchainAccountId": "eip155:1:0xb9c5714089478a327f09197987f16f9e5d936e8a"
}
],
"authentication": ["did:moon:0xb9c5714089478a327f09197987f16f9e5d936e8a#controller"],
"assertionMethod": ["did:moon:0xb9c5714089478a327f09197987f16f9e5d936e8a#controller"]
}
Note this resolver uses the EcdsaSecp256k1RecoveryMethod2020
type and an blockchainAccountId
to represent the
default
verificationMethod
, assertionMethod
, and authentication
entry. Any value from the registry that returns an
ethereum address will be added to the verificationMethod
array of the DID document with
type EcdsaSecp256k1RecoveryMethod2020
and an blockchainAccountId
attribute containing the address.
The DID document is not stored as a file, but is built by using read only functions and contract events on the ethr-did-registry Ethereum smart contract.
Please see the spec for details of how the DID document and corresponding metadata are computed.
The library presents a resolve()
function that returns a Promise
returning the DID document. It is not meant to be
used directly but through the did-resolver
aggregator.
You can use the getResolver(config)
method to produce an entry that can be used with the Resolver
constructor:
import { Resolver } from 'did-resolver'
import { getResolver } from 'moon-did-resolver'
// While experimenting, you can set a rpc endpoint to be used by the web3 provider
// You can also set the address for your own moon-did-registry contract
const providerConfig = { rpcUrl: 'http://localhost:7545', registry: registry.address }
// It's recommended to use the multi-network configuration when using this in production
// since that allows you to resolve on multiple public and private networks at the same time.
// getResolver will return an object with a key/value pair of { "moon": resolver } where resolver is a function used by the generic did resolver.
const moonDidResolver = getResolver(providerConfig)
const didResolver = new Resolver(moonDidResolver)
didResolver.resolve('did:moon:0xf3beac30c498d9e26865f34fcaa57dbb935b0d74').then((doc) => console.log)
// You can also use ES7 async/await syntax
const doc = await didResolver.resolve('did:moon:0xf3beac30c498d9e26865f34fcaa57dbb935b0d74')
In production, you will most likely want the ability to resolve DIDs that are based in different ethereum networks. To do this, you need a configuration that sets the network name or chain ID (and even the registry address) for each network. An example configuration for multi-network DID resolving would look like this:
const providerConfig = {
networks: [
{ name: 'dev', rpcUrl: 'http://localhost:7545', registry: '0xdca7ef03e98e0dc2b855be647c39abe984fcf21b' },
{ name: 'alpha', chainId: 1287, registry: '0x1205411db2cC925253A57299f3313075DDD48439' },
],
}
const moonDidResolver = getResolver(providerConfig)
The configuration from above allows you to resolve moon-did's of the following formats:
did:moon:mainnet:0xabcabc03e98e0dc2b855be647c39abe984193675
did:moon:0xabcabc03e98e0dc2b855be647c39abe984193675
(defaults to mainnet configuration)did:moon:alpha:0xabcabc03e98e0dc2b855be647c39abe984193675
did:moon:0x507:0xabcabc03e98e0dc2b855be647c39abe984193675
(refer to the moon:alpha by chainID)did:moon:dev:0xabcabc03e98e0dc2b855be647c39abe984193675
did:moon:myprivatenet:0xabcabc03e98e0dc2b855be647c39abe984193675
did:moon:0x1e240:0xabcabc03e98e0dc2b855be647c39abe984193675
(refer tomyprivatenet
by chainID)
For each network you can specify either an rpcUrl
, a provider
or a web3
instance that can be used to access that
particular network. At least one of name
or chainId
must be specified per network.
These providers will have to support eth_call
and eth_getLogs
to be able to resolve DIDs specific to that network.
You can also override the default registry address by specifying a registry
attribute per network.