HTTPBIS Working Group | D. Schinazi |
Internet-Draft | Google LLC |
Intended status: Standards Track | D. Oliver |
Expires: March 14, 2025 | Guardian Project |
J. Hoyland | |
Cloudflare Inc. | |
September 10, 2024 |
Most HTTP authentication schemes are probeable in the sense that it is possible for an unauthenticated client to probe whether an origin serves resources that require authentication. It is possible for an origin to hide the fact that it requires authentication by not generating Unauthorized status codes, however that only works with non-cryptographic authentication schemes: cryptographic signatures require a fresh nonce to be signed. Prior to this document, there was no existing way for the origin to share such a nonce without exposing the fact that it serves resources that require authentication. This document defines a new non-probeable cryptographic authentication scheme.¶
This note is to be removed before publishing as an RFC.¶
The latest revision of this draft can be found at <https://httpwg.org/http-extensions/draft-ietf-httpbis-unprompted-auth.html>. Status information for this document may be found at <https://datatracker.ietf.org/doc/draft-ietf-httpbis-unprompted-auth/>.¶
Discussion of this document takes place on the HTTP Working Group mailing list (<mailto:ietf-http-wg@w3.org>), which is archived at <https://lists.w3.org/Archives/Public/ietf-http-wg/>. Working Group information can be found at <https://httpwg.org/>.¶
Source for this draft and an issue tracker can be found at <https://github.com/httpwg/http-extensions/labels/unprompted-auth>.¶
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Internet-Drafts are working documents of the Internet Engineering Task Force (IETF). Note that other groups may also distribute working documents as Internet-Drafts. The list of current Internet-Drafts is at https://datatracker.ietf.org/drafts/current/.¶
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Copyright (c) 2024 IETF Trust and the persons identified as the document authors. All rights reserved.¶
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HTTP authentication schemes (see Section 11 of [HTTP]) allow origins to restrict access for some resources to only authenticated requests. While these schemes commonly involve a challenge where the origin asks the client to provide authentication information, it is possible for clients to send such information unprompted. This is particularly useful in cases where an origin wants to offer a service or capability only to "those who know" while all others are given no indication the service or capability exists. Such designs rely on an externally-defined mechanism by which keys are distributed. For example, a company might offer remote employee access to company services directly via its website using their employee credentials, or offer access to limited special capabilities for specific employees, while making discovering (or probing for) such capabilities difficult. As another example, members of less well-defined communities might use more ephemeral keys to acquire access to geography- or capability-specific resources, as issued by an entity whose user base is larger than the available resources can support (by having that entity metering the availability of keys temporally or geographically).¶
While digital-signature-based HTTP authentication schemes already exist (e.g., [HOBA]), they rely on the origin explicitly sending a fresh challenge to the client, to ensure that the signature input is fresh. That makes the origin probeable as it sends the challenge to unauthenticated clients. This document defines a new signature-based authentication scheme that is not probeable.¶
The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT", "SHOULD", "SHOULD NOT", "RECOMMENDED", "NOT RECOMMENDED", "MAY", and "OPTIONAL" in this document are to be interpreted as described in BCP 14 [RFC2119] [RFC8174] when, and only when, they appear in all capitals, as shown here.¶
This document uses the notation from Section 1.3 of [QUIC].¶
This document defines the "Concealed" HTTP authentication scheme. It uses asymmetric cryptography. Clients possess a key ID and a public/private key pair, and origin servers maintain a mapping of authorized key IDs to associated public keys.¶
The client uses a TLS keying material exporter to generate data to be signed (see Section 3) then sends the signature using the Authorization (or Proxy-Authorization) header field (see Section 11 of [HTTP]). The signature and additional information are exchanged using authentication parameters (see Section 4). Once the server receives these, it can check whether the signature validates against an entry in its database of known keys. The server can then use the validation result to influence its response to the client, for example by restricting access to certain resources.¶
When a client wishes to use the Concealed HTTP authentication scheme with a request, it SHALL compute the authentication proof using a TLS keying material exporter with the following parameters:¶
Note that TLS 1.3 keying material exporters are defined in Section 7.5 of [TLS], while TLS 1.2 keying material exporters are defined in [KEY-EXPORT].¶
Signature Algorithm (16), Key ID Length (i), Key ID (..), Public Key Length (i), Public Key (..), Scheme Length (i), Scheme (..), Host Length (i), Host (..), Port (16), Realm Length (i), Realm (..),
Figure 1: Key Exporter Context Format
The key exporter context contains the following fields:¶
The Signature Algorithm and Port fields are encoded as unsigned 16-bit integers in network byte order. The Key ID, Public Key, Scheme, Host, and Realm fields are length prefixed strings; they are preceded by a Length field that represents their length in bytes. These length fields are encoded using the variable-length integer encoding from Section 16 of [QUIC] and MUST be encoded in the minimum number of bytes necessary.¶
Both the "Public Key" field of the TLS key exporter context (see above) and the a Parameter (see Section 4.2) carry the same public key. The encoding of the public key is determined by the Signature Algorithm in use as follows:¶
This document does not define the public key encodings for other algorithms. In order for a SignatureScheme to be usable with the Concealed HTTP authentication scheme, its public key encoding needs to be defined in a corresponding document.¶
The key exporter output is 48 bytes long. Of those, the first 32 bytes are part of the input to the signature and the next 16 bytes are sent alongside the signature. This allows the recipient to confirm that the exporter produces the right values. This is described in Figure 2:¶
Signature Input (256), Verification (128),
Figure 2: Key Exporter Output Format
The key exporter output contains the following fields:¶
Once the Signature Input has been extracted from the key exporter output (see Section 3.2), it is prefixed with static data before being signed to mitigate issues caused by key reuse. The signature is computed over the concatenation of:¶
For example, if the Signature Input has all its 32 bytes set to 01, the content covered by the signature (in hexadecimal format) would be:¶
2020202020202020202020202020202020202020202020202020202020202020 2020202020202020202020202020202020202020202020202020202020202020 48545450205369676E61747572652041757468656E7469636174696F6E 00 0101010101010101010101010101010101010101010101010101010101010101
Figure 3: Example Content Covered by Signature
This construction mirrors that of the TLS 1.3 CertificateVerify message defined in Section 4.4.3 of [TLS].¶
The resulting signature is then transmitted to the server using the p Parameter (see Section 4.3).¶
This specification defines the following authentication parameters.¶
All of the byte sequences below are encoded using base64url (see Section 5 of [BASE64]) without quotes and without padding. In other words, the values of these byte-sequence authentication parameters MUST NOT include any characters other then ASCII letters, digits, dash and underscore.¶
The integer below is encoded without a minus and without leading zeroes. In other words, the value of this integer authentication parameter MUST NOT include any characters other than digits, and MUST NOT start with a zero unless the full value is "0".¶
concealed-byte-sequence-param-value = *( ALPHA / DIGIT / "-" / "_" ) concealed-integer-param-value = %x31-39 1*4( DIGIT ) / "0"
Figure 4: Authentication Parameter Value ABNF
The REQUIRED "k" (key ID) Parameter is a byte sequence that identifies which key the client wishes to use to authenticate. This is used by the backend to point to an entry in a server-side database of known keys, see Section 6.3.¶
The REQUIRED "a" (public key) Parameter is a byte sequence that specifies the public key used by the server to validate the signature provided by the client. This avoids key confusion issues (see [SEEMS-LEGIT]). The encoding of the public key is described in Section 3.1.1.¶
The REQUIRED "p" (proof) Parameter is a byte sequence that specifies the proof that the client provides to attest to possessing the credential that matches its key ID.¶
The REQUIRED "s" (signature) Parameter is an integer that specifies the signature scheme used to compute the proof transmitted in the p Parameter. Its value is an integer between 0 and 65535 inclusive from the IANA "TLS SignatureScheme" registry maintained at <https://www.iana.org/assignments/tls-parameters/tls-parameters.xhtml#tls-signaturescheme>.¶
The REQUIRED "v" (verification) Parameter is a byte sequence that specifies the verification that the client provides to attest to possessing the key exporter output (see Section 3.2 for details). This avoids issues with signature schemes where certain keys can generate signatures that are valid for multiple inputs (see [SEEMS-LEGIT]).¶
For example, the key ID "basement" authenticating using Ed25519 [ED25519] could produce the following header field:¶
NOTE: '\' line wrapping per RFC 8792
Authorization: Concealed \ k=YmFzZW1lbnQ, \ a=VGhpcyBpcyBh-HB1YmxpYyBrZXkgaW4gdXNl_GhlcmU, \ s=2055, \ v=dmVyaWZpY2F0aW9u_zE2Qg, \ p=QzpcV2luZG93c_xTeXN0ZW0zMlxkcml2ZXJz-ENyb3dkU\ 3RyaWtlXEMtMDAwMDAwMDAyOTEtMD-wMC0w_DAwLnN5cw
Figure 5: Example Header Field
In this section, we subdivide the server role in two:¶
In most deployments, we expect the frontend and backend roles to both be implemented in a single HTTP origin server (as defined in Section 3.6 of [HTTP]). However, these roles can be split such that the frontend is an HTTP gateway (as defined in Section 3.7 of [HTTP]) and the backend is an HTTP origin server.¶
If a frontend is configured to check the Concealed authentication scheme, it will parse the Authorization (or Proxy-Authorization) header field. If the authentication scheme is set to "Concealed", the frontend MUST validate that all the required authentication parameters are present and can be parsed correctly as defined in Section 4. If any parameter is missing or fails to parse, the frontend MUST ignore the entire Authorization (or Proxy-Authorization) header field.¶
The frontend then uses the data from these authentication parameters to compute the key exporter output, as defined in Section 3.2. The frontend then shares the header field and the key exporter output with the backend.¶
If the frontend and backend roles are implemented in the same machine, this can be handled by a simple function call.¶
If the roles are split between two separate HTTP servers, then the backend won't be able to directly access the TLS keying material exporter from the TLS connection between the client and frontend, so the frontend needs to explictly send it. This document defines the "Concealed-Auth-Export" request header field for this purpose. The Concealed-Auth-Export header field's value is a Structured Field Byte Sequence (see Section 3.3.5 of [STRUCTURED-FIELDS]) that contains the 48-byte key exporter output (see Section 3.2), without any parameters. For example:¶
NOTE: '\' line wrapping per RFC 8792
Concealed-Auth-Export: :VGhpcyBleGFtcGxlIFRMUyBleHBvcn\
RlciBvdXRwdXQgaXMgNDggYnl0ZXMgI/+h:
Figure 6: Example Concealed-Auth-Export Header Field
The frontend SHALL forward the HTTP request to the backend, including the original unmodified Authorization (or Proxy-Authorization) header field and the newly added Concealed-Auth-Export header field.¶
Note that, since the security of this mechanism requires the key exporter output to be correct, backends need to trust frontends to send it truthfully. This trust relationship is common because the frontend already needs access to the TLS certificate private key in order to respond to requests. HTTP servers that parse the Concealed-Auth-Export header field MUST ignore it unless they have already established that they trust the sender. Similarly, frontends that send the Concealed-Auth-Export header field MUST ensure that they do not forward any Concealed-Auth-Export header field received from the client.¶
Once the backend receives the Authorization (or Proxy-Authorization) header field and the key exporter output, it looks up the key ID in its database of public keys. The backend SHALL then perform the following checks:¶
If all of these checks succeed, the backend can consider the request to be properly authenticated, and can reply accordingly (the backend can also forward the request to another HTTP server).¶
If any of the above checks fail, the backend MUST treat it as if the Authorization (or Proxy-Authorization) header field was missing.¶
Servers that wish to introduce resources whose existence cannot be probed need to ensure that they do not reveal any information about those resources to unauthenticated clients. In particular, such servers MUST respond to authentication failures with the exact same response that they would have used for non-existent resources. For example, this can mean using HTTP status code 404 (Not Found) instead of 401 (Unauthorized).¶
The authentication checks described above can take time to compute, and an attacker could detect use of this mechanism if that time is observable by comparing the timing of a request for a known non-existent resource to the timing of a request for a potentially authenticated resource. Servers can mitigate this observability by slightly delaying responses to some non-existent resources such that the timing of the authentication verification is not observable. This delay needs to be carefully considered to avoid having the delay itself leak the fact that this origin uses this mechanism at all.¶
Non-probeable resources also need to be non-discoverable for unauthenticated users. For example, if a server operator wishes to hide an authenticated resource by pretending it does not exist to unauthenticated users, then the server operator needs to ensure there are no unauthenticated pages with links to that resource, and no other out-of-band ways for unauthenticated users to discover this resource.¶
This authentication scheme is only defined for uses of HTTP with TLS [TLS]. This includes any use of HTTP over TLS as typically used for HTTP/2 [HTTP/2], or HTTP/3 [HTTP/3] where the transport protocol uses TLS as its authentication and key exchange mechanism [QUIC-TLS].¶
Because the TLS keying material exporter is only secure for authentication when it is uniquely bound to the TLS session [RFC7627], the Concealed authentication scheme requires either one of the following properties:¶
Clients MUST NOT use the Concealed authentication scheme on connections that do not meet one of the two properties above. If a server receives a request that uses this authentication scheme on a connection that meets neither of the above properties, the server MUST treat the request as if the authentication were not present.¶
The Concealed HTTP authentication scheme allows a client to authenticate to an origin server while guaranteeing freshness and without the need for the server to transmit a nonce to the client. This allows the server to accept authenticated clients without revealing that it supports or expects authentication for some resources. It also allows authentication without the client leaking the presence of authentication to observers due to clear-text TLS Client Hello extensions.¶
Since the freshness described above is provided by a TLS key exporter, it can be as old as the underlying TLS connection. Servers can require better freshness by forcing clients to create new connections using mechanisms such as the GOAWAY frame (see Section 5.2 of [HTTP/3]).¶
The authentication proofs described in this document are not bound to individual HTTP requests; if the key is used for authentication proofs on multiple requests on the same connection, they will all be identical. This allows for better compression when sending over the wire, but implies that client implementations that multiplex different security contexts over a single HTTP connection need to ensure that those contexts cannot read each other's header fields. Otherwise, one context would be able to replay the Authorization header field of another. This constraint is met by modern Web browsers. If an attacker were to compromise the browser such that it could access another context's memory, the attacker might also be able to access the corresponding key, so binding authentication to requests would not provide much benefit in practice.¶
Key material used for the Concealed HTTP authentication scheme MUST NOT be reused in other protocols. Doing so can undermine the security guarantees of the authentication.¶
Origins offering this scheme can link requests that use the same key. However, requests are not linkable across origins if the keys used are specific to the individual origins using this scheme.¶
This document, if approved, requests IANA to register the following entry in the "HTTP Authentication Schemes" Registry maintained at <https://www.iana.org/assignments/http-authschemes>:¶
This document, if approved, requests IANA to register the following entry in the "TLS Exporter Labels" registry maintained at <https://www.iana.org/assignments/tls-parameters#exporter-labels>:¶
This document, if approved, requests IANA to register the following entry in the "Hypertext Transfer Protocol (HTTP) Field Name" registry maintained at <https://www.iana.org/assignments/http-fields/http-fields.xhtml>:¶
The authors would like to thank many members of the IETF community, as this document is the fruit of many hallway conversations. In particular, the authors would like to thank David Benjamin, Reese Enghardt, Nick Harper, Dennis Jackson, Ilari Liusvaara, François Michel, Lucas Pardue, Justin Richer, Ben Schwartz, Martin Thomson, and Chris A. Wood for their reviews and contributions. The mechanism described in this document was originally part of the first iteration of MASQUE [MASQUE-ORIGINAL].¶