Internet-Draft | Batched Tokens | March 2023 |
Robert & Wood | Expires 14 September 2023 | [Page] |
This document specifies a variant of the Privacy Pass issuance protocol that allows for batched issuance of tokens. This allows clients to request more than one token at a time and for issuers to isse more than one token at a time.¶
This Internet-Draft is submitted in full conformance with the provisions of BCP 78 and BCP 79.¶
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/.¶
Internet-Drafts are draft documents valid for a maximum of six months and may be updated, replaced, or obsoleted by other documents at any time. It is inappropriate to use Internet-Drafts as reference material or to cite them other than as "work in progress."¶
This Internet-Draft will expire on 14 September 2023.¶
Copyright (c) 2023 IETF Trust and the persons identified as the document authors. All rights reserved.¶
This document is subject to BCP 78 and the IETF Trust's Legal Provisions Relating to IETF Documents (https://trustee.ietf.org/license-info) in effect on the date of publication of this document. Please review these documents carefully, as they describe your rights and restrictions with respect to this document. Code Components extracted from this document must include Revised BSD License text as described in Section 4.e of the Trust Legal Provisions and are provided without warranty as described in the Revised BSD License.¶
This document specifies a variant of the Privacy Pass issuance protocol (as defined in [ARCH]) that allows for batched issuance of tokens. This allows clients to request more than one token at a time and for issuers to isse more than one token at a time.¶
The base Privacy Pass issuance protocol [ISSUANCE] defines stateless anonymous tokens, which can either be publicly verifiable or not. While it is possible to run multiple instances of the issuance protocol in parallel, e.g., over a multiplexed transport such as HTTP/3 [HTTP3], the cost of doing so scales linearly with the number of instances.¶
This variant builds upon the privately verifiable issuance protocol that uses VOPRF [OPRF], and allows for batched issuance of tokens. This allows clients to request more than one token at a time and for issuers to issue more than one token at a time. In effect, batched issuance performance scales better than linearly.¶
This issuance protocol registers the batched token type (Section 7.1), to be used with the PrivateToken HTTP authentication scheme defined in [AUTHSCHEME].¶
Privately Verifiable Tokens (as defines in [ISSUANCE]) offer a simple way to unlink the issuance from the redemption. The base protocol however only allows for a single token to be issued at a time for every challenge. In some cases, especially where a large number of clients need to fetch a large number of tokens, this may introduce performance bottlenecks. The Batched Token Issuance Protocol improves upon the basic Privately Verifiable Token issuance protocol in the following key ways:¶
Except where specified otherwise, the client follows the same protocol as described in [ISSUANCE], Section 5.1.¶
The Client first creates a context as follows:¶
client_context = SetupVOPRFClient("ristretto255-SHA512", pkI)¶
Here, "ristretto255-SHA512" is the identifier corresponding to the OPRF(ristretto255, SHA-512) ciphersuite in [OPRF]. SetupVOPRFClient is defined in [OPRF], Section 3.2.¶
Nr
denotes the number of tokens the clients wants to request. For every token,
the Client then creates an issuance request message for a random value nonce
with the input challenge and Issuer key identifier as described below:¶
nonce_i = random(32) challenge_digest = SHA256(challenge) token_input = concat(0xF91A, nonce_i, challenge_digest, key_id) blind_i, blinded_element_i = client_context.Blind(token_input)¶
The above is repeated for each token to be requested. Importantly, a fresh nonce MUST be sampled each time.¶
The Client then creates a TokenRequest structured as follows:¶
struct { uint8_t blinded_element[Ne]; } BlindedElement; struct { uint16_t token_type = 0xF91A; uint8_t token_key_id; BlindedElement blinded_elements<0..2^16-1>; } TokenRequest;¶
The structure fields are defined as follows:¶
key_id
in network byte
order (in other words, the last 8 bits of key_id
).¶
Nr
serialized elements, each of length Ne
bytes and computed as SerializeElement(blinded_element_i)
, where
blinded_element_i is the i-th output sequence of Blind
invocations above. Ne
is as defined in [OPRF], Section 4.¶
Upon receipt of the request, the Issuer validates the following conditions:¶
If any of these conditions is not met, the Issuer MUST return an HTTP 400 error to the client.¶
Except where specified otherwise, the client follows the same protocol as described in [ISSUANCE], Section 5.2.¶
Upon receipt of a TokenRequest, the Issuer tries to deseralize the i-th element
of TokenRequest.blinded_elements using DeserializeElement from Section 2.1 of [OPRF], yielding blinded_element_i
of type Element
. If this fails for any of
the TokenRequest.blinded_elements values, the Issuer MUST return an HTTP 400
error to the client. Otherwise, if the Issuer is willing to produce a token to
the Client, the issuer forms a list of Element
values, denoted
blinded_elements
, and computes a blinded response as follows:¶
server_context = SetupVOPRFServer("ristretto255-SHA512", skI, pkI) evaluated_elements, proof = server_context.BlindEvaluateBatch(skI, blinded_elements)¶
SetupVOPRFServer is defined in [OPRF], Section 3.2. The issuer uses a list of
blinded elements to compute in the proof generation step. The
BlindEvaluateBatch
function is a batch-oriented version of the BlindEvaluate
function described in [OPRF], Section 3.3.2. The description of
BlindEvaluateBatch
is below.¶
Input: Element blindedElements[Nr] Output: Element evaluatedElements[Nr] Proof proof Parameters: Group G Scalar skS Element pkS def BlindEvaluateBatch(blindedElements): evaluatedElements = [] for blindedElement in blindedElements: evaluatedElements.append(skS * blindedElement) proof = GenerateProof(skS, G.Generator(), pkS, blindedElements, evaluatedElements) return evaluatedElements, proof¶
The Issuer then creates a TokenResponse structured as follows:¶
struct { uint8_t evaluated_element[Ne]; } EvaluatedElement; struct { EvaluatedElement evaluated_elements<0..2^16-1>; uint8_t evaluated_proof[Ns + Ns]; } TokenResponse;¶
The structure fields are defined as follows:¶
Nr
serialized elements, each of length
Ne
bytes and computed as SerializeElement(evaluate_element_i)
, where
evaluate_element_i is the i-th output of BlindEvaluate
.¶
concat(SerializeScalar(proof[0]),
SerializeScalar(proof[1]))
, where Ns is as defined in [OPRF], Section 4.¶
Upon receipt, the Client handles the response and, if successful, deserializes
the body values TokenResponse.evaluate_response and
TokenResponse.evaluate_proof, yielding evaluated_elements
and proof
. If
deserialization of either value fails, the Client aborts the protocol.
Otherwise, the Client processes the response as follows:¶
authenticator_values = client_context.FinalizeBatch(token_input, blind, evaluated_elements, blinded_elements, proof)¶
The FinalizeBatch
function is a batched variant of the Finalize
function as
defined in [OPRF], Section 3.3.2. FinalizeBatch
accepts lists of evaluated
elements and blinded elements as input parameters, and is implemented as
described below:¶
Input: PrivateInput input Scalar blind Element evaluatedElements[Nr] Element blindedElements[Nr] Proof proof Output: opaque output[Nh * Nr] Parameters: Group G Element pkS Errors: VerifyError def FinalizeBatch(input, blind, evaluatedElements, blindedElements, proof): if VerifyProof(G.Generator(), pkS, blindedElements, evaluatedElements, proof) == false: raise VerifyError output = nil for evaluatedElement in evaluatedElements: N = G.ScalarInverse(blind) * evaluatedElement unblindedElement = G.SerializeElement(N) hashInput = I2OSP(len(input), 2) || input || I2OSP(len(unblindedElement), 2) || unblindedElement || "Finalize" output = concat(output, Hash(hashInput)) return output¶
If this succeeds, the Client then constructs Nr
Token values as follows, where
authenticator
is the i-th Nh-byte length slice of authenticator_values
that
corresponds to nonce
, the i-th nonce that was sampled in
Section 3:¶
struct { uint16_t token_type = 0xF91A uint8_t nonce[32]; uint8_t challenge_digest[32]; uint8_t token_key_id[32]; uint8_t authenticator[Nh]; } Token;¶
If the FinalizeBatch function fails, the Client aborts the protocol.¶
Implementors SHOULD be aware of the security considerations described in [OPRF], Section 6.2.3 and implement mitigation mechanisms. Application can mitigate this issue by limiting the number of clients and limiting the number of token requests per client per key.¶
This document updates the "Token Type" Registry ([AUTHSCHEME]) with the following value:¶
Value | Name | Publicly Verifiable | Public Metadata | Private Metadata | Nk | Reference |
---|---|---|---|---|---|---|
0xF91A | Batched Token VOPRF (ristretto255, SHA-512) | N | N | N | 32 | This document |