BBS per Verifier Linkability
draft-vasilis-bbs-per-verifier-linkability-00
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draft-vasilis-bbs-per-verifier-linkability-00
CFRG V. Kalos
Internet-Draft MATTR
Intended status: Informational G. Bernstein
Expires: 19 September 2024 Grotto Networking
18 March 2024
BBS per Verifier Linkability
draft-vasilis-bbs-per-verifier-linkability-00
Abstract
The BBS Signatures scheme describes a multi-message digital
signature, that supports selectively disclosing the messages through
unlinkable presentations, build using zero-knowledge proofs. Each
BBS proof reveals no information other than the signed messages that
the Prover chooses to disclose in that specific instance. As such,
the Verifier (i.e., the recipient) of the BBS proof, may not be able
to track those presentations over time. Although in many
applications this is desirable, there are use cases where that
require from the Verifier, to be able to track the BBS proofs they
receive from the same entity. Examples include monitoring the use of
access credentials for abnormal activity, monetization etc.. This
document presents the use of pseudonyms with BBS proofs. A
pseudonym, is a value that will remain constant each time a Prover
presents a BBS proof to the same Verifier, but will be different (and
unlinkable), when the Prover interacts with different parties. This
provides a way for a recipient to track the presentations intended
for them, while also hindering them from tracking the Prover's
interactions with other Verifiers.
Status of This Memo
This Internet-Draft is submitted in full conformance with the
provisions of BCP 78 and BCP 79.
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material or to cite them other than as "work in progress."
This Internet-Draft will expire on 19 September 2024.
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Copyright Notice
Copyright (c) 2024 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
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provided without warranty as described in the Revised BSD License.
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . 3
1.1. Terminology . . . . . . . . . . . . . . . . . . . . . . . 4
1.2. Notation . . . . . . . . . . . . . . . . . . . . . . . . 5
2. Conventions and Definitions . . . . . . . . . . . . . . . . . 6
3. Preliminaries . . . . . . . . . . . . . . . . . . . . . . . . 6
3.1. Pseudonyms . . . . . . . . . . . . . . . . . . . . . . . 6
3.2. Prover Identifier . . . . . . . . . . . . . . . . . . . . 7
3.3. Mapping Messages to Scalars . . . . . . . . . . . . . . . 7
4. BBS with Pseudonym Interface . . . . . . . . . . . . . . . . 8
4.1. Signature Generation and Verification . . . . . . . . . . 8
4.2. Proof Generation with Pseudonym . . . . . . . . . . . . . 9
4.2.1. Calculate Pseudonym . . . . . . . . . . . . . . . . . 9
4.2.2. Proof Generation . . . . . . . . . . . . . . . . . . 10
4.3. Proof Verification with Pseudonym . . . . . . . . . . . . 12
5. Core Operations . . . . . . . . . . . . . . . . . . . . . . . 14
5.1. Core Proof Generation . . . . . . . . . . . . . . . . . . 14
5.2. Core Proof Verification . . . . . . . . . . . . . . . . . 16
6. Utility Operations . . . . . . . . . . . . . . . . . . . . . 18
6.1. Challenge Calculation . . . . . . . . . . . . . . . . . . 18
7. Security Considerations . . . . . . . . . . . . . . . . . . . 20
8. Ciphersuites . . . . . . . . . . . . . . . . . . . . . . . . 20
9. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 20
10. Normative References . . . . . . . . . . . . . . . . . . . . 20
11. Informative References . . . . . . . . . . . . . . . . . . . 21
Appendix A. Acknowledgments . . . . . . . . . . . . . . . . . . 21
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . 21
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1. Introduction
BBS Signatures, defined in [I-D.irtf-cfrg-bbs-signatures] and
originally described in the academic work by Dan Boneh, Xavier Boyen,
and Hovav Shacham [BBS04], is a signature scheme able to sign
multiple messages at once, allowing for selectively disclosing those
message while not revealing the signature it self. It does so by
creating unlinkable, zero-knowledge proofs-of-knowledge of a
signature value on (among other) the disclosed set of messages. More
specifically, the BBS Prover, will create a BBS proof that if
validated by the Verifier, guarantees that the prover knows a BBS
signature on the disclosed messages, guaranteeing this way the
revealed messages authenticity and integrity.
The BBS Proof is by design unlinkable, meaning that given 2 different
BBS proofs, there is no way to tell if they originated from the same
BBS signature. This means that if a Prover does not reveal any other
identifying information (for example if they are using proxies to
hide their IP address etc.), the Verifier of the proof will not be
able "track" the different proof presentations or the Provers
activity. This is done to guarantee privacy in applications where
the Verifier only needs to know that the Prover is in possession of a
valid BBS signature over a list of disclosed messages. In a lot of
applications however, the Verifier needs to track the presentations
made by the Prover over time, as to provide security monitoring,
monetization services, configuration persistance etc.. That said, for
obvious privacy reasons, the Prover should not reveal a unique
identifier that would remain constant across proof presentations to
different Verifiers (like their IP address).
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The goal of this document is to provide a way for a Verifier to track
the proof presentations that are intended for them, while at the same
time not allowing the tracking of the Prover's activity to other
Verifiers. This is done through the use of Pseudonyms. A pseudonym
as defined by this document, is a value that will be constant when
the Prover presents BBS proofs to the same Verifier, but will change
when the Prover interacts with different recipients (with no way to
link the 2 distinguee pseudonym values together). This is done by
constructing the pseudonym value by combining a unique Verifier
identifier with a unique Prover identifier. To avoid forging
requests, the Prover's identifier will be signed by the same BBS
signature used to generate the BBS proof. This allows extending the
BBS proof generation and verification operations with some additional
computations, that will be used to prove correctness of the
pseudonym, i.e., that it was correctly calculated using the Verifier
identifier, as well as, the undisclosed and signed Prover identifier.
The Prover identifier MUST be considered secret from the Prover,
since, if it is revealed, any entity will be able to track the
Prover's activity across all Verifiers.
This document will define a new BBS Interface for use with
pseudonyms, however it will not define new ciphersuites. Rather it
will re-use the ciphersuites defined in Section 6
(https://www.ietf.org/archive/id/draft-irtf-cfrg-bbs-signatures-
03.html#name-ciphersuites) of [I-D.irtf-cfrg-bbs-signatures]).
1.1. Terminology
The following terminology is used throughout this document:
SK The secret key for the signature scheme.
PK The public key for the signature scheme.
L The total number of signed messages.
R The number of message indexes that are disclosed (revealed) in a
proof-of-knowledge of a signature.
U The number of message indexes that are undisclosed in a proof-of-
knowledge of a signature.
scalar An integer between 0 and r-1, where r is the prime order of
the selected groups, defined by each ciphersuite (see also
Notation (#notation)).
generator A valid point on the selected subgroup of the curve being
used that is employed to commit a value.
signature The digital signature output.
presentation_header (ph) A payload generated and bound to the
context of a specific spk.
INVALID, ABORT Error indicators. INVALID refers to an error
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encountered during the Deserialization or Procedure steps of an
operation. An INVALID value can be returned by a subroutine and
handled by the calling operation. ABORT indicates that one or
more of the initial constraints defined by the operation are not
met. In that case, the operation will stop execution. An
operation calling a subroutine that aborted must also immediately
abort.
1.2. Notation
The following notation and primitives are used:
a || b Denotes the concatenation of octet strings a and b.
I \ J For sets I and J, denotes the difference of the two sets i.e.,
all the elements of I that do not appear in J, in the same order
as they were in I.
X[a..b] Denotes a slice of the array X containing all elements from
and including the value at index a until and including the value
at index b. Note when this syntax is applied to an octet string,
each element in the array X is assumed to be a single byte.
range(a, b) For integers a and b, with a <= b, denotes the ascending
ordered list of all integers between a and b inclusive (i.e., the
integers "i" such that a <= i <= b).
length(input) Takes as input either an array or an octet string. If
the input is an array, returns the number of elements of the
array. If the input is an octet string, returns the number of
bytes of the inputted octet string.
Terms specific to pairing-friendly elliptic curves that are relevant
to this document are restated below, originally defined in
[I-D.irtf-cfrg-pairing-friendly-curves].
E1, E2 elliptic curve groups defined over finite fields. This
document assumes that E1 has a more compact representation than
E2, i.e., because E1 is defined over a smaller field than E2. For
a pairing-friendly curve, this document denotes operations in E1
and E2 in additive notation, i.e., P + Q denotes point addition
and x * P denotes scalar multiplication.
G1, G2 subgroups of E1 and E2 (respectively) having prime order r.
GT a subgroup, of prime order r, of the multiplicative group of a
field extension.
e G1 x G2 -> GT: a non-degenerate bilinear map.
r The prime order of the G1 and G2 subgroups.
BP1, BP2 base (constant) points on the G1 and G2 subgroups
respectively.
Identity_G1, Identity_G2, Identity_GT The identity element for the
G1, G2, and GT subgroups respectively.
hash_to_curve_g1(ostr, dst) -> P A cryptographic hash function that
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takes an arbitrary octet string as input and returns a point in
G1, using the hash_to_curve operation defined in
[I-D.irtf-cfrg-hash-to-curve] and the inputted dst as the domain
separation tag for that operation (more specifically, the inputted
dst will become the DST parameter for the hash_to_field operation,
called by hash_to_curve).
point_to_octets_g1(P) -> ostr, point_to_octets_g2(P) -> ostr returns
the canonical representation of the point P for the respective
subgroup as an octet string. This operation is also known as
serialization.
octets_to_point_g1(ostr) -> P, octets_to_point_g2(ostr) -> P returns
the point P for the respective subgroup corresponding to the
canonical representation ostr, or INVALID if ostr is not a valid
output of the respective point_to_octets_g* function. This
operation is also known as deserialization.
2. Conventions and Definitions
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.
3. Preliminaries
3.1. Pseudonyms
This document defines a pseudonym as point of the G1 group different
from the Identity (Identity_G1) or the base point (BP1) of G1. A
pseudonym remains constant for each Prover and Verifier pair, but is
unique (and unlinkable) across different Provers or Verifiers. In
other words, when the Prover presents multiple BBS proofs with a
pseudonym to a Verifier, the pseudonym value will be constant across
those presentations. When presenting a BBS proof with a pseudonym to
another Verifier however, the pseudonym value will be different.
Note that since pseudonyms are group points, their value will
necessarily change if a different a ciphersuite with a different
curve will be used. This document specifies pseudonyms to be BBS
Interface specific (see Section TBD of [I-D.irtf-cfrg-bbs-signatures]
for the definition of the BBS Interface). It is outside the scope of
this document to provide a procedure for "linking" the pseudonyms
that are used by different Interfaces or that are based on different
ciphersuites. An option is for the Prover to present both Pseudonyms
with the relevant BBS proofs to the Verifier, and upon validation of
both, the Verifier to internally link the 2 pseudonyms together.
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3.2. Prover Identifier
Each pseudonym is constructed from a unique Prover Identifier (pid),
which is an octet string that MUST be at least 32 octets long. The
pid value will be the last message signed by the BBS signature. In
this document the Prover Identifier is chosen by the BBS Signer.
This gives the Signer the ability to track the Prover even when they
present BBS proofs with pseudonyms to different Verifiers. To avoid
this threat, the Prover can choose and "commit" the pid value
themselves, using Blind BBS Signatures, as defined in TBD. In any
case, the pid value MUST be the last signed message. It also MUST
unique across different Provers with very high probability.
Additionally, it MUST be indistinguishable from a random value, drawn
from the uniform distribution over the space of all octet strings
that are at least 32 octets long. Such value could be generated from
a cryptographically secure pseudo-random number generator. See
[DRBG] for requirements and suggestions on generating randomness.
As mentioned above, the pseudonym value is defined as a point of the
G1 group. Serialization and deserialization of the pseudonym point
MUST be done using the point_to_octets_g1 and octets_to_point_g1
defined by the BBS ciphersuite used (see Section 6
(https://www.ietf.org/archive/id/draft-irtf-cfrg-bbs-signatures-
03.html#name-ciphersuites) of [I-D.irtf-cfrg-bbs-signatures]).
3.3. Mapping Messages to Scalars
Each BBS Interface defines an operation that will map the inputted
messages to scalar values, required by the core BBS operations. Each
Interface can use a different mapping procedure, as long as it
comforts to the requirements outlined in TBD. For using BBS with
pseudonyms, the mapping operation used by the interface is REQUIRED
to additionally adhere the following rule;
For each set of messages and separate message msg',
if C1 = messages_to_scalars(messages.push(msg')),
and msg_prime_scalar = messages_to_scalars((msg')),
and C2 = messages_to_scalars(messages).push(msg_prime_scalar),
it will always hold that C1 == C2.
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Informally, the above means that each message is mapped to a scalar
independently from all the other messages. For example, if a =
messages_to_scalars((msg_1)) and b = messages_to_scalars((msg_2)),
then (a, b) = messages_to_scalars((msg_1, msg_2)). Its trivial to
see that the messages_to_scalars operation that is defined in
Section TBD of [I-D.irtf-cfrg-bbs-signatures], has the required
property. That operation will be used by the Interface defined in
this document to map the messages to scalars. Note that the above
operation (and hence the defined by this document Interface), only
accepts messages that are octet strings.
4. BBS with Pseudonym Interface
The following section defines a BBS Interface that will make use of
per-origin pseudonyms. The identifier of the Interface is defined as
ciphersuite_id || H2G_HM2S_PSEUDONYM_, where ciphersuite_id the
unique identifier of the BBS ciphersuite used, as is defined in
Section 6 (https://www.ietf.org/archive/id/draft-irtf-cfrg-bbs-
signatures-03.html#name-ciphersuites) of
[I-D.irtf-cfrg-bbs-signatures]). Each BBS Interface MUST define
operations to map the inputted messages to scalar values and to
create the generators set, required by the core operations. The
inputted messages to the defined in this document BBS Interface will
be mapped to scalars using the messages_to_scalars operation defined
in Section TBD of [I-D.irtf-cfrg-bbs-signatures]. The generators
will be created using the create_generators operation defined in
Section TBD of [I-D.irtf-cfrg-bbs-signatures].
This document also defines 2 alternative core proof generation and
verification operations (see Section 5), to accommodate the use of
pseudonyms. Those operations will be used by the defined proof
generation and verification Interface operations, in place of the
CoreProofGen and CoreProofVerify operations defined in Section TBD of
[I-D.irtf-cfrg-bbs-signatures].
4.1. Signature Generation and Verification
The Issuer of the BBS signature will include a constant unique prover
identifier (pid) as one of the signed messages. The format of that
identifier is outside the scope of this document. An options is to
use a pseudo random generator to return 32 random octets. The pid
value MUST be the last one in the set of signed messages.
More specifically, the Signer to generate a signature from a secret
key (SK), a constant Prover identifier (pid) and optionally over a
header and or a vector of messages, MUST execute the following steps,
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1. messages = messages.push(pid)
2. signature = Sign(SK, PK, header, messages)
Where Sign is defined in Section 3.4.1
(https://www.ietf.org/archive/id/draft-irtf-cfrg-bbs-signatures-
03.html#name-signature-generation-sign) of
[I-D.irtf-cfrg-bbs-signatures], instantiated with the api_id
parameter set to the value ciphersuite_id || H2G_HM2S_PSEUDONYM_,
where ciphersuite_id the unique identifier of the ciphersuite.
To verify the above signature, for a given pid, header and vector of
messages, against a supplied public key (PK), the Prover MUST execute
the following steps,
1. messages = messages.push(pid)
2. signature = Verify(PK, signature, header, messages)
The Verify operation is defined in Section 3.4.2
(https://www.ietf.org/archive/id/draft-irtf-cfrg-bbs-signatures-
03.html#name-signature-verification-veri) of
[I-D.irtf-cfrg-bbs-signatures], instantiated with the api_id
parameter set to the value ciphersuite_id || H2G_HM2S_PSEUDONYM_,
where ciphersuite_id the unique identifier of the ciphersuite.
4.2. Proof Generation with Pseudonym
This section defines operations for generating a pseudonym, as well
as using it to calculate a BBS proof. The BBS proof is extended to
include a zero-knowledge proof of correctness of the pseudonym value,
i.e., that is correctly calculated using the (undisclosed) id of the
Prover (pid), and that is "bound" to the underlying BBS signature
(i.e., that the pid value is signed by the Signer).
4.2.1. Calculate Pseudonym
The following operation describes how to calculate a pseudonym from
the Prover's and the Verifier's unique identifiers (IDs), as well as
a BBS Interface identifier (api_id, see TBD). The pseudonym will be
unique for different Verifier and interface IDs and constant under
constant inputs (i.e., the same verifier_id, pid and api_id values).
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pseudonym = CalculatePseudonym(verifier_id, pid, api_id)
Inputs:
- verifier_id (REQUIRED), an octet string, representing the unique proof
Verifier identifier.
- pid (REQUIRED), an octet string, representing the unique Prover
identifier.
- api_id (OPTIONAL), an octet string. If not supplied it defaults to the
empty octet string ("").
Outputs:
- pseudonym, A point of G1, different from the Identity_G1, BP1 and P1
(see the Parameters of this operation); or INVALID.
Parameters:
- hash_to_curve_g1, the hash_to_curve operation defined by the Hash to
Curve suite determined by the ciphersuite, through
the hash_to_curve_suite parameter.
- P1, fixed point of G1, defined by the ciphersuite.
Procedure:
1. OP = hash_to_curve_g1(verifier_id, api_id)
2. if OP is INVALID, return INVALID
3. if OP == Identity_G1 or OP == BP1 or OP == P1, return INVALID
3. pid_scalar = messages_to_scalars((pid), api_id)
4. return OP * pid_scalar
4.2.2. Proof Generation
Thi operation computes a BBS proof with a pseudonym, which is a zero-
knowledge, proof-of-knowledge, of a BBS signature, while optionally
disclosing any subset of the signed messages. The BBS proof is
extended to also include a zero-knowledge proof of correctness of the
pseudonym, meaning that it is correctly calculated, using a signed
Prover identifier and the supplied Verifier's ID.
Validating the proof (see ProofVerifyWithPseudonym defined in
Section 4.3), guarantees authenticity and integrity of the header,
presentation header and disclosed messages, knowledge of a valid BBS
signature as well as correctness and ownership of the pseudonym.
This operation makes use of CoreProofGenWithPseudonym as defined in
Section 5.1.
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proof = ProofGenWithPseudonym(PK,
signature,
Pseudonym,
verifier_id,
pid,
header,
ph,
messages,
disclosed_indexes)
Inputs:
- PK (REQUIRED), an octet string of the form outputted by the SkToPk
operation.
- signature (REQUIRED), an octet string of the form outputted by the
Sign operation.
- Pseudonym (REQUIRED), A point of G1, different from the Identity of
G1, as outputted by the CalculatePseudonym
operation.
- verifier_id (REQUIRED), an octet string, representing the unique proof
Verifier identifier.
- pid (REQUIRED), an octet string, representing the unique Prover
identifier.
- header (OPTIONAL), an octet string containing context and application
specific information. If not supplied, it defaults
to an empty string.
- ph (OPTIONAL), an octet string containing the presentation header. If
not supplied, it defaults to an empty string.
- messages (OPTIONAL), a vector of octet strings. If not supplied, it
defaults to the empty array "()".
- disclosed_indexes (OPTIONAL), vector of unsigned integers in ascending
order. Indexes of disclosed messages. If
not supplied, it defaults to the empty
array "()".
Parameters:
- api_id, the octet string ciphersuite_id || "H2G_HM2S_PSEUDONYM_",
where ciphersuite_id is defined by the ciphersuite and
"H2G_HM2S_PSEUDONYM_" is an ASCII string comprised of
9 bytes.
Outputs:
- proof, an octet string; or INVALID.
Procedure:
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1. message_scalars = messages_to_scalars(messages, api_id)
2. pid_scalar = messages_to_scalars((pid), api_id)
3. generators = create_generators(length(messages) + 2, PK, api_id)
4. proof = CoreProofGenWithPseudonym(PK,
signature,
Pseudonym,
verifier_id,
pid_scalar,
generators,
header,
ph,
message_scalars,
disclosed_indexes,
api_id)
5. if proof is INVALID, return INVALID
6. return proof
4.3. Proof Verification with Pseudonym
This operation validates a BBS proof with a pseudonym, given the
Signer's public key (PK), the proof, the pseudonym and the Verifier's
identifier that was used to create it, a header and presentation
header, the disclosed messages and lastly, the indexes those messages
had in the original vector of signed messages. Validating the proof
also validates the correctness and ownership by the Prover of the
received pseudonym.
This operation makes use of CoreProofVerifyWithPseudonym as defined
in Section 5.2.
result = ProofVerifyWithPseudonym(PK,
proof,
Pseudonym,
verifier_id,
header,
ph,
disclosed_indexes,
disclosed_messages)
Inputs:
- PK (REQUIRED), an octet string of the form outputted by the SkToPk
operation.
- proof (REQUIRED), an octet string of the form outputted by the
ProofGen operation.
- Pseudonym (REQUIRED), A point of G1, different from the Identity of
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G1, as outputted by the CalculatePseudonym
operation.
- verifier_id (REQUIRED), an octet string, representing the unique proof
Verifier identifier.
- header (OPTIONAL), an optional octet string containing context and
application specific information. If not supplied,
it defaults to an empty string.
- ph (OPTIONAL), an octet string containing the presentation header. If
not supplied, it defaults to an empty string.
- disclosed_messages (OPTIONAL), a vector of octet strings. If not
supplied, it defaults to the empty
array "()".
- disclosed_indexes (OPTIONAL), vector of unsigned integers in ascending
order. Indexes of disclosed messages. If
not supplied, it defaults to the empty
array "()".
Parameters:
- api_id, the octet string ciphersuite_id || "H2G_HM2S_PSEUDONYM_",
where ciphersuite_id is defined by the ciphersuite and
"H2G_HM2S_PSEUDONYM_" is an ASCII string comprised of
9 bytes.
- (octet_point_length, octet_scalar_length), defined by the ciphersuite.
Outputs:
- result, either VALID or INVALID.
Deserialization:
1. proof_len_floor = 2 * octet_point_length + 3 * octet_scalar_length
2. if length(proof) < proof_len_floor, return INVALID
3. U = floor((length(proof) - proof_len_floor) / octet_scalar_length)
4. R = length(disclosed_indexes)
5. L = U + R
Procedure:
1. message_scalars = messages_to_scalars(disclosed_messages, api_id)
2. generators = create_generators(L + 1, PK, api_id)
3. result = CoreProofVerifyWithPseudonym(PK,
proof,
Pseudonym,
verifier_id,
generators,
header,
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ph,
message_scalars,
disclosed_indexes,
api_id)
4. return result
5. Core Operations
This section defines the core operations used by the
ProofGenWithPseudonym and ProofVerifyWithPseudonym operations defined
in Section 4.2 and Section 4.3 correspondingly. Those operations are
handling the main mathematical procedures required to compute and
validate the BBS with pseudonym proof.
5.1. Core Proof Generation
This operations computes a BBS proof and a zero-knowledge proof of
correctness of the pseudonym in "parallel" (meaning using common
randomness), as to both create a proof that the pseudonym was
correctly calculated using an undisclosed value that the Prover knows
(i.e., the pid value), but also that this value is "signed" by the
BBS signature (the last undisclosed message). As a result,
validating the proof guarantees that the pseudonym is correctly
computed and that it was computed using the Prover identifier that
was included in the BBS signature.
The operation uses the ProofInit and ProofFinalize operations defined
in TBD and the ProofWithPseudonymChallengeCalculate defined in
Section 6.1.
proof = CoreProofGenWithPseudonym(PK,
signature,
Pseudonym,
verifier_id,
pid_scalar,
generators,
header,
ph,
messages,
disclosed_indexes,
api_id)
Inputs:
- PK (REQUIRED), an octet string of the form outputted by the SkToPk
operation.
- signature (REQUIRED), an octet string of the form outputted by the
Sign operation.
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- Pseudonym (REQUIRED), A point of G1, different from the Identity of
G1, as outputted by the CalculatePseudonym
operation.
- verifier_id (REQUIRED), an octet string, representing the unique proof
Verifier identifier.
- pid_scalar (REQUIRED), a scalar value, representing the unique Prover
identifier after it is mapped to a scalar.
- generators (REQUIRED), vector of points in G1.
- header (OPTIONAL), an octet string containing context and application
specific information. If not supplied, it defaults
to an empty string.
- ph (OPTIONAL), an octet string containing the presentation header. If
not supplied, it defaults to an empty string.
- messages (OPTIONAL), a vector of scalars representing the messages.
If not supplied, it defaults to the empty
array "()".
- disclosed_indexes (OPTIONAL), vector of unsigned integers in ascending
order. Indexes of disclosed messages. If
not supplied, it defaults to the empty
array "()".
- api_id (OPTIONAL), an octet string. If not supplied it defaults to the
empty octet string ("").
Parameters:
- P1, fixed point of G1, defined by the ciphersuite.
Outputs:
- proof, an octet string; or INVALID.
Deserialization:
1. signature_result = octets_to_signature(signature)
2. if signature_result is INVALID, return INVALID
3. (A, e) = signature_result
4. messages = messages.push(pid_scalar)
5. L = length(messages)
6. R = length(disclosed_indexes)
7. (i1, ..., iR) = disclosed_indexes
8. if R > L, return INVALID
9. U = L - R
10. undisclosed_indexes = range(1, L) \ disclosed_indexes
11. disclosed_messages = (messages[i1], ..., messages[iR])
ABORT if:
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1. for i in disclosed_indexes, i < 1 or i > L - 1
Procedure:
1. random_scalars = calculate_random_scalars(3+U)
2. init_res = ProofInit(PK,
signature_res,
header,
random_scalars,
generators,
messages,
undisclosed_indexes,
api_id)
3. if init_res is INVALID, return INVALID
4. OP = hash_to_curve_g1(verifier_id)
5. pid~ = random_scalars[3+U] // last element of random_scalars
6. U = OP * pid~
7. pseudonym_init_res = (Pseudonym, OP, U)
8. challenge = ProofWithPseudonymChallengeCalculate(init_res,
pseudonym_init_res,
disclosed_indexes,
disclosed_messages,
ph,
api_id)
9. proof = ProofFinalize(challenge, e, random_scalars, messages,
undisclosed_indexes)
10. return proof_to_octets(proof)
5.2. Core Proof Verification
This operation validates a BBS proof that also includes a pseudonym.
Validating the proof, other than the correctness and integrity of the
revealed messages, the header and the presentation header values,
also guarantees that the supplied pseudonym was correctly calculated,
i.e., that it was produced using the Verifier's identifier and the
signed (but undisclosed) Prover's identifier, following the
CalculatePseudonym operation defined in Section 4.2.1.
The operation uses the ProofVerifyInit operation defined in TBD and
the ProofWithPseudonymChallengeCalculate defined in Section 6.1.
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result = CoreProofVerifyWithPseudonym(PK,
proof,
Pseudonym,
verifier_id,
generators,
header,
ph,
disclosed_messages,
disclosed_indexes,
api_id)
Inputs:
- PK (REQUIRED), an octet string of the form outputted by the SkToPk
operation.
- proof (REQUIRED), an octet string of the form outputted by the
ProofGen operation.
- Pseudonym (REQUIRED), A point of G1, different from the Identity of
G1, as outputted by the CalculatePseudonym
operation.
- verifier_id (REQUIRED), an octet string, representing the unique proof
Verifier identifier.
- generators (REQUIRED), vector of points in G1.
- header (OPTIONAL), an optional octet string containing context and
application specific information. If not supplied,
it defaults to an empty string.
- ph (OPTIONAL), an octet string containing the presentation header. If
not supplied, it defaults to an empty string.
- disclosed_messages (OPTIONAL), a vector of scalars representing the
messages. If not supplied, it defaults
to the empty array "()".
- disclosed_indexes (OPTIONAL), vector of unsigned integers in ascending
order. Indexes of disclosed messages. If
not supplied, it defaults to the empty
array "()".
- api_id (OPTIONAL), an octet string. If not supplied it defaults to the
empty octet string ("").
Parameters:
- P1, fixed point of G1, defined by the ciphersuite.
Outputs:
- result, either VALID or INVALID.
Deserialization:
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1. proof_result = octets_to_proof(proof)
2. if proof_result is INVALID, return INVALID
3. (Abar, Bbar, r2^, r3^, commitments, cp) = proof_result
4. W = octets_to_pubkey(PK)
5. if W is INVALID, return INVALID
6. R = length(disclosed_indexes)
7. (i1, ..., iR) = disclosed_indexes
ABORT if:
1. for i in disclosed_indexes, i < 1 or i > R + length(commitments) - 1
Procedure:
1. init_res = ProofVerifyInit(PK, proof_result, header, generators,
messages, disclosed_indexes, api_id)
2. OP = hash_to_curve_g1(verifier_id)
3. U = length(commitments)
4. pid^ = commitments[U] // last element of the commitments
5. Uv = OP * pid^ - Pseudonym * cp
6. pseudonym_init_res = (Pseudonym, OP, Uv)
7. challenge = ProofWithPseudonymChallengeCalculate(init_res,
pseudonym_init_res,
disclosed_indexes,
messages,
ph,
api_id)
8. if cp != challenge, return INVALID
9. if e(Abar, W) * e(Bbar, -BP2) != Identity_GT, return INVALID
10. return VALID
6. Utility Operations
6.1. Challenge Calculation
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challenge = ProofWithPseudonymChallengeCalculate(init_res,
pseudonym_init_res,
i_array,
msg_array,
ph)
Inputs:
- init_res (REQUIRED), vector representing the value returned after
initializing the proof generation or verification
operations, consisting of 3 points of G1 and a
scalar value, in that order.
- pseudonym_init_res (REQUIRED), vector representing the value returned
after initializing the pseudonym proof,
consisting of 3 points of G1.
- i_array (REQUIRED), array of non-negative integers (the indexes of
the disclosed messages).
- msg_array (REQUIRED), array of scalars (the disclosed messages after
mapped to scalars).
- ph (OPTIONAL), an octet string. If not supplied, it must default to
the empty octet string ("").
Outputs:
- challenge, a scalar.
Deserialization:
1. R = length(i_array)
2. (i1, ..., iR) = i_array
3. (msg_i1, ..., msg_iR) = msg_array
4. (Abar, Bbar, C, domain) = init_res
5. (Pseudonym, OP, U) = pseudonym_init_res
ABORT if:
1. R > 2^64 - 1 or R != length(msg_array)
2. length(ph) > 2^64 - 1
Procedure:
1. c_arr = (Abar, Bbar, C, Pseudonym, OP, U, R, i1, ..., iR,
msg_i1, ..., msg_iR, domain)
2. c_octs = serialize(c_array)
3. return hash_to_scalar(c_octs || I2OSP(length(ph), 8) || ph)
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7. Security Considerations
TODO Security
8. Ciphersuites
This document does not define new BBS ciphersuites. Its ciphersuite
defined in Section 6 (https://www.ietf.org/archive/id/draft-irtf-
cfrg-bbs-signatures-03.html#name-ciphersuites) of
[I-D.irtf-cfrg-bbs-signatures]) can be used to instantiate the
operations of the described scheme.
9. IANA Considerations
This document has no IANA actions.
10. Normative References
[I-D.irtf-cfrg-bbs-signatures]
Looker, T., Kalos, V., Whitehead, A., and M. Lodder, "The
BBS Signature Scheme", Work in Progress, Internet-Draft,
draft-irtf-cfrg-bbs-signatures-05, 21 December 2023,
<https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-
bbs-signatures-05>.
[I-D.irtf-cfrg-hash-to-curve]
Faz-Hernandez, A., Scott, S., Sullivan, N., Wahby, R. S.,
and C. A. Wood, "Hashing to Elliptic Curves", Work in
Progress, Internet-Draft, draft-irtf-cfrg-hash-to-curve-
16, 15 June 2022, <https://datatracker.ietf.org/doc/html/
draft-irtf-cfrg-hash-to-curve-16>.
[I-D.irtf-cfrg-pairing-friendly-curves]
Sakemi, Y., Kobayashi, T., Saito, T., and R. S. Wahby,
"Pairing-Friendly Curves", Work in Progress, Internet-
Draft, draft-irtf-cfrg-pairing-friendly-curves-11, 6
November 2022, <https://datatracker.ietf.org/doc/html/
draft-irtf-cfrg-pairing-friendly-curves-11>.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119,
DOI 10.17487/RFC2119, March 1997,
<https://www.rfc-editor.org/info/rfc2119>.
[RFC8174] Leiba, B., "Ambiguity of Uppercase vs Lowercase in RFC
2119 Key Words", BCP 14, RFC 8174, DOI 10.17487/RFC8174,
May 2017, <https://www.rfc-editor.org/info/rfc8174>.
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11. Informative References
[BBS04] Boneh, D., Boyen, X., and H. Shacham, "Short Group
Signatures", In Advances in Cryptology, pages 41-55, 2004,
<https://link.springer.com/
chapter/10.1007/978-3-540-28628-8_3>.
[DRBG] NIST, "Recommendation for Random Number Generation Using
Deterministic Random Bit Generators",
<https://nvlpubs.nist.gov/nistpubs/SpecialPublications/
NIST.SP.800-90Ar1.pdf>.
Appendix A. Acknowledgments
TODO acknowledge.
Authors' Addresses
Vasilis Kalos
MATTR
Email: vasilis.kalos@mattr.global
Greg M. Bernstein
Grotto Networking
Email: gregb@grotto-networking.com
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