📜EIP-4361
EIP-4361: Sign-In with Ethereum
Last updated
EIP-4361: Sign-In with Ethereum
Last updated
Sign-In with Ethereum describes how Ethereum accounts authenticate with off-chain services by signing a standard message format parameterized by scope, session details, and security mechanisms (e.g., a nonce). The goals of this specification are to provide a self-custodied alternative to centralized identity providers, improve interoperability across off-chain services for Ethereum-based authentication, and provide wallet vendors a consistent machine-readable message format to achieve improved user experiences and consent management.
When signing in to popular non-blockchain services today, users will typically use identity providers (IdPs) that are centralized entities with ultimate control over users’ identifiers, for example, large internet companies and email providers. Incentives are often misaligned between these parties. Sign-In with Ethereum offers a new self-custodial option for users who wish to assume more control and responsibility over their own digital identity.
Already, many services support workflows to authenticate Ethereum accounts using message signing, such as to establish a cookie-based web session which can manage privileged metadata about the authenticating address. This is an opportunity to standardize the sign-in workflow and improve interoperability across existing services, while also providing wallet vendors a reliable method to identify signing requests as Sign-In with Ethereum requests for improved UX.
Sign-In with Ethereum works as follows:
The wallet presents the user with a structured plaintext message or equivalent interface for signing with the EIP-191 signature scheme (string prefixed with \x19Ethereum Signed Message:\n<length of message>
). The message
MUST incorporate an Ethereum address
, domain
requesting the signing, version
of the message, a chain identifier chain-id
, uri
for scoping, nonce
acceptable to the server, and issued-at
timestamp.
The signature is then presented to the server, which checks the signature's validity and message content.
Additional fields, including expiration-time
, not-before
, request-id
, chain-id
, and resources
may be incorporated as part of authentication for the session.
The server may further fetch data associated with the Ethereum address, such as from the Ethereum blockchain (e.g., ENS, account balances, ERC-20/ERC-721/ERC-1155 asset ownership), or other data sources that may or may not be permissioned.
A Bash-like informal template of the full message is presented below for readability and ease of understanding. Field descriptions are provided in the following section. A full ABNF description is provided in the section thereafter.
authority
is the RFC 3986 authority
that is requesting the signing.
address
is the Ethereum address performing the signing conformant to capitalization encoded checksum specified in EIP-55 where applicable.
statement
(optional) is a human-readable ASCII assertion that the user will sign, and it must not contain '\n'
(the byte 0x0a
).
uri
is an RFC 3986 URI referring to the resource that is the subject of the signing (as in the subject of a claim).
version
is the current version of the message
, which MUST be 1
for this specification.
chain-id
is the EIP-155 Chain ID to which the session is bound, and the network where Contract Accounts must be resolved.
nonce
is a randomized token used to prevent replay attacks, at least 8 alphanumeric characters.
issued-at
is the ISO 8601 datetime string of the current time.
expiration-time
(optional) is the ISO 8601 datetime string that, if present, indicates when the signed authentication message is no longer valid.
not-before
(optional) is the ISO 8601 datetime string that, if present, indicates when the signed authentication message will become valid.
request-id
(optional) is an system-specific identifier that may be used to uniquely refer to the sign-in request.
resources
(optional) is a list of information or references to information the user wishes to have resolved as part of authentication by the relying party. They are expressed as RFC 3986 URIs separated by "\n- "
.
The message
to be signed MUST conform with the following Augmented Backus–Naur Form (ABNF, RFC 5234) expression (note that %s
denotes case sensitivity for a string term, as per RFC 7405).
Signing and Verifying with Ethereum Accounts
For Externally Owned Accounts (EOAs), the verification method specified in EIP-191 MUST be used.
For Contract Accounts,
The verification method specified in EIP-1271 SHOULD be used, and if it is not, the implementer MUST clearly define the verification method to attain security and interoperability for both wallets and relying parties.
When performing EIP-1271 signature verification, the contract performing the verification MUST be resolved from the specified chain-id
.
Implementers SHOULD take into consideration that EIP-1271 implementations are not required to be pure functions, and can return different results for the same inputs depending on blockchain state. This can affect the security model and session validation rules. For example, a service with EIP-1271 signing enabled could rely on webhooks to receive notifications when state affecting the results is changed. When it receives a notification, it invalidates any matching sessions.
The server or wallet MAY additionally perform resolution of ENS data, as this can improve the user experience by displaying a human-friendly information that is related to the address
. Resolvable ENS data include:
The primary ENS name.
The ENS avatar.
Any other resolvable resources specified in the documentation.
If resolution of ENS data is performed, implementers SHOULD take precautions to preserve user privacy and consent, as their address
could be forwarded to third party services as part of the resolution process.
Verifying a signed message
The message MUST be checked for conformance to the ABNF above, checked against expected term values after parsing, and its signature must be verified.
Creating sessions
Sessions MUST be bound to the address
and not to further resolved resources that may change.
Interpreting and resolving resources
The listed resources
must be RFC 3986 URIs, but their interpretation is out of scope of this specification.
Implementers SHOULD ensure that that URIs are human-friendly when expressed in plaintext form.
Verifying message
The full message
MUST be checked for conformance to the ABNF above.
Wallet implementers SHOULD warn users if the substring "wants you to sign in with your Ethereum account"
appears anywhere in an EIP-191 message signing request unless the message fully conforms to the format defined in this specification.
Verifying domain
binding
Wallet implementers MUST prevent phishing attacks by matching on the domain
term when processing a signing request. For example, when processing the message beginning with "service.invalid wants you to sign in..."
, the wallet checks that the request actually originated from service.invalid
.
The domain SHOULD be read from a trusted data source such as the browser window or over WalletConnect (EIP-1328) sessions for comparison against the signing message contents.
Creating Sign-In with Ethereum interfaces
Wallet implementers MUST display to the user the following terms from the Sign-In with Ethereum signing request by default and prior to signing, if they are present: domain
, address
, statement
, and resources
. Other present terms MUST also be made available to the user prior to signing either by default or through an extended interface.
Wallet implementers displaying a plaintext message
to the user SHOULD require the user to scroll to the bottom of the text area prior to signing.
Wallet implementers MAY construct a custom Sign-In With Ethereum user interface by parsing the ABNF terms into data elements for use in the interface. The display rules above still apply to custom interfaces.
Supporting internationalization (i18n)
After successfully parsing the message into ABNF terms, translation may happen at the UX level per human language.
Write a specification for how Sign-In with Ethereum should work. The specification should be simple and generally follow existing practices. Avoid feature bloat, particularly the inclusion of lesser-used projects who see getting into the specification as a means of gaining adoption. The core specification should be decentralized, open, non-proprietary, and have long-term viability. It should have no dependence on a centralized server except for the servers already being run by the application that the user is signing in to. The basic specification should include: Ethereum accounts used for authentication, ENS names for usernames (via reverse resolution), and data from the ENS name’s text records for additional profile information (e.g. avatar, social media handles, etc).
Additional functional requirements:
The user must be presented a human-understandable interface prior to signing, mostly free of machine-targeted artifacts such as JSON blobs, hex codes (aside from the Ethereum address), and baseXX-encoded strings.
The application server must be able to implement fully usable support for its end without forcing a change in the wallets.
There must be a simple and straightforward upgrade path for both applications and wallets already using Ethereum account-based signing for authentication.
There must be facilities and guidelines for adequate mitigation of Man-in-the-Middle (MITM) attacks, replay attacks, and malicious signing requests.
Human-Friendly
Simple to Implement
Secure
Machine Readable
Extensible
Why EIP-191 (Signed Data Standard) over EIP-712 (Ethereum typed structured data hashing and signing)
EIP-712 has the advantage of on-chain representation and on-chain verifiability, such as for their use in metatransactions, but this feature is not relevant for the specification’s scope. (2)
Why not use JWTs? Wallets don’t support JWTs. The keccak hash function is not assigned by IANA for use as a JOSE algorithm. (2, 3)
Why not use YAML or YAML with exceptions? YAML is loose compared to ABNF, which can readily express character set limiting, required ordering, and strict whitespacing. (2, 3)
The following concerns are out of scope for this version of the specification to define:
Additional authentication not based on Ethereum addresses.
Authorization to server resources.
Interpretation of the URIs in the resources
term as claims or other resources.
The specific mechanisms to ensure domain-binding.
The specific mechanisms to generate nonces and evaluation of their appropriateness.
Protocols for use without TLS connections.
The following items are considered for future support in either through an iteration of this specification or new work items using this specification as a dependency.
Possible support for Decentralized Identifiers and Verifiable Credentials.
Possible cross-chain support.
Possible SIOPv2 support.
Possible future support for EIP-712.
Version interpretation rules, e.g., sign with minor revision greater than understood, but not greater major version.
Most wallet implementations already support EIP-191, so this is used as a base pattern with additional features.
Requirements were gathered from existing implementations of similar sign-in workflows, including statements to allow the user to accept a Terms of Service, nonces for replay protection, and inclusion of the Ethereum address itself in the message.
A reference implementation is available here.
Identifier reuse
Towards perfect privacy, it would be ideal to use a new uncorrelated identifier (e.g., Ethereum address) per digital interaction, selectively disclosing the information required and no more.
This concern is less relevant to certain user demographics who are likely to be early adopters of this specification, such as those who manage an Ethereum address and/or ENS names intentionally associated with their public presence. These users often prefer identifier reuse to maintain a single correlated identity across many services.
This consideration will become increasingly important with mainstream adoption. There are several ways to move towards this model, such as using HD wallets, signed delegations, and zero-knowledge proofs. However, these approaches are out of scope for this specification and better suited for follow-on specifications.
Key management
Sign-In with Ethereum gives users control through their keys. This is additional responsibility that mainstream users may not be accustomed to accepting, and key management is a hard problem especially for individuals. For example, there is no "forgot password" button as centralized identity providers commonly implement.
Early adopters of this specification are likely to be already adept at key management, so this consideration becomes more relevant with mainstream adoption.
Certain wallets can use smart contracts and multisigs to provide an enhanced user experiences with respect to key usage and key recovery, and these can be supported via EIP-1271 signing.
Wallet and server combined security
Both the wallet and server must implement this specification for improved security to the end user. Specifically, the wallet MUST confirm that the message is for the correct domain
or provide the user means to do so manually (such as instructions to visually confirming the correct domain in a TLS-protected website prior to connecting via QR code or deeplink), otherwise the user is subject to phishing attacks.
Minimizing wallet and server interaction
In some implementions of wallet sign-in workflows, the server first sends parameters of the message
to the wallet. Others generate the message for signing entirely in the client side (e.g., dapps). The latter approach without initial server interaction SHOULD be preferred when there is a user privacy advantage by minimizing wallet-server interaction. Often, the backend server first produces a nonce
to prevent replay attacks, which it verifies after signing. Privacy-preserving alternatives are suggested in the next section on preventing replay attacks.
Before the wallet presents the message signing request to the user, it MAY consult the server for the proper contents of the message to be signed, such as an acceptable nonce
or requested set of resources
. When communicating to the server, the wallet SHOULD take precautions to protect user privacy by mitigating user information revealed as much as possible.
Prior to signing, the wallet MAY consult the user for preferences, such as the selection of one address
out of many, or a preferred ENS name out of many.
Preventing replay attacks
A nonce
should be selected per session initiation with enough entropy to prevent replay attacks, a man-in-the-middle attack in which an attacker is able to capture the user's signature and resend it to establish a new session for themselves.
Implementers MAY consider using privacy-preserving yet widely-available nonce
values, such as one derived from a recent Ethereum block hash or a recent Unix timestamp.
Verification of domain binding
Wallets MUST check that the domain
matches the the actual signing request source.
This value SHOULD be checked against a trusted data source such as the browser window or over another protocol.
Channel security
For web-based applications, all communications SHOULD use HTTPS to prevent man-in-the-middle attacks on the message signing.
When using protocols other than HTTPS, all communications SHOULD be protected with proper techniques to maintain confidentiality, data integrity, and sender/receiver authenticity.
Session invalidation
There are several cases where an implementer SHOULD check for state changes as they relate to sessions.
If an EIP-1271 implementation or dependent data changes the signature computation, the server SHOULD invalidate sessions appropriately.
If any resources specified in resources
change, the server SHOULD invalidate sessions appropriately. However, the interpretation of resources
is out of scope of this specification.
Maximum lengths for ABNF terms
While this specification does not contain normative requirements around maximum string lengths, implementers SHOULD choose maximum lengths for terms that strike a balance across the prevention of denial of service attacks, support for arbitrary use cases, and user readability.
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