Internet-Draft | VDAF | December 2024 |
Barnes, et al. | Expires 9 June 2025 | [Page] |
This document describes Verifiable Distributed Aggregation Functions (VDAFs), a family of multi-party protocols for computing aggregate statistics over user measurements. These protocols are designed to ensure that, as long as at least one aggregation server executes the protocol honestly, individual measurements are never seen by any server in the clear. At the same time, VDAFs allow the servers to detect if a malicious or misconfigured client submitted an invalid measurement. Two concrete VDAFs are specified, one for general-purpose aggregation (Prio3) and another for heavy hitters (Poplar1).¶
This note is to be removed before publishing as an RFC.¶
Discussion of this document takes place on the Crypto Forum Research Group mailing list (cfrg@ietf.org), which is archived at https://mailarchive.ietf.org/arch/search/?email_list=cfrg.¶
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Copyright (c) 2024 IETF Trust and the persons identified as the document authors. All rights reserved.¶
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(RFC EDITOR: remove this paragraph.) The source for this draft and the reference implementation can be found at https://github.com/cfrg/draft-irtf-cfrg-vdaf.¶
The ubiquity of the Internet makes it an ideal platform for measurement of large-scale phenomena, whether public health trends or the behavior of computer systems at scale. There is substantial overlap, however, between information that is valuable to measure and information that users consider private.¶
For example, consider an application that provides health information to users. The operator of an application might want to know which parts of their application are used most often, as a way to guide future development of the application. Specific users' patterns of usage, though, could reveal sensitive things about them, such as which users are researching a given health condition.¶
In many situations, the measurement collector is only interested in aggregate statistics, e.g., which portions of an application are most used or what fraction of people have experienced a given disease. Thus systems that provide aggregate statistics while protecting individual measurements can deliver the value of the measurements while protecting users' privacy.¶
This problem is often formulated in terms of differential privacy (DP) [Dwo06]. Roughly speaking, a data aggregation system that is differentially private ensures that the degree to which any individual measurement influences the value of the aggregate result can be precisely controlled. For example, in systems like RAPPOR [EPK14], each user samples noise from a well-known distribution and adds it to their measurement before submitting to the aggregation server. The aggregation server then adds up the noisy measurements, and because it knows the distribution from which the noise was sampled, it can estimate the true sum with reasonable accuracy.¶
Even when noise is added to the measurements, collecting them in the clear still reveals a significant amount of information to the collector. On the one hand, depending on the "amount" of noise a client adds to its measurement, it may be possible for a curious collector to make a reasonable guess of the measurement's true value. On the other hand, the more noise the clients add, the less reliable will be the server's estimate of the aggregate. Thus systems relying solely on a DP mechanism must strike a delicate balance between privacy and utility.¶
Another way of constructing a privacy-preserving measurement system is to use multi-party computation (MPC). The goal of such a system is that no participant in the protocol should learn anything about an individual measurement beyond what it can deduce from the aggregate. MPC achieves this goal by distributing the computation of the aggregate across multiple aggregation servers, one of which is presumed to be honest, i.e., not under control of the attacker. Moreover, MPC can be composed with various DP mechanisms to ensure the aggregate itself does not leak too much information about any one of the measurements [MPRV09].¶
This document describes two classes of MPC protocols, each aiming for a different set of goals.¶
In a Distributed Aggregation Function (DAF, Section 4), each client splits its measurement into multiple secret shares, one for each aggregation server. DAFs require two properties of the secret sharing scheme. First, we can reconstruct the underlying measurement by simply adding up all of the shares. (Typically the shares are vectors over some finite field.) Second, given all but one of the shares, it is impossible to learn anything about the underlying measurement. These properties give rise to a simple strategy for privately aggregating the measurements: each aggregation server adds up its measurement shares locally before revealing their sum to the data collector; then all the data collector has to do is add up these sums to get the aggregate result.¶
This strategy is compatible with any aggregation function that can be represented as the sum of some encoding of the measurements. Examples include: summary statistics such as sum, mean, and standard deviation; estimation of quantiles, e.g., median; histograms; linear regression; or counting data structures, e.g., Bloom filters. However, not all functions fit into this rubric, as it is constrained to linear computations over the encoded measurements.¶
In fact, our framework admits DAFs with slightly more functionality, computing aggregation functions of the form¶
F(agg_param, meas_1, ..., meas_M) = G(agg_param, meas_1) + ... + G(agg_param, meas_M)¶
where meas_1, ..., meas_M
are the measurements, G
is a possibly
non-linear function, and agg_param
is a parameter of that function chosen by
the data collector. This paradigm, known as function secret sharing [BGI15],
allows for more sophisticated data analysis tasks, such as grouping metrics by
private client attributes [MPDST25] or computing heavy hitters [BBCGGI21].
(More on the latter task below.)¶
The second class of protocols defined in this document are called Verifiable Distributed Aggregation Functions (VDAFs, Section 5). In addition to being private, VDAFs are verifiable in the following sense. By design, a secret sharing of a valid measurement, e.g., a number between 1 and 10, is indistinguishable from a secret sharing of an invalid measurement, e.g., a number larger than 10. This means that DAFs are vulnerable to attacks from malicious clients attempting to disrupt the computation by submitting invalid measurements. VDAFs are designed to allow the servers to detect and remove these measurements prior to aggregation. We refer to this property as robustness.¶
Achieving robustness without sacrificing privacy requires the servers to interact with one another over a number of rounds of communication. DAFs on the other hand are non-interactive, making them easier to deploy; but they do not provide robustness on their own. This may be tolerable in some applications. For instance, if the client's software is executed in a trusted execution environment, it may be reasonable to assume that no client is malicious.¶
The DAF and VDAF abstractions encompass a variety of MPC techniques in the literature. These protocols vary in their operational and security requirements, sometimes in subtle but consequential ways. This document therefore has two important goals:¶
Provide higher-level protocols, like [DAP], with a simple, uniform interface for accessing privacy-preserving measurement schemes, document relevant operational and security requirements, and specify constraints for safe usage:¶
General patterns of communications among the various actors involved in the system (clients, aggregation servers, and the collector of the aggregate result);¶
Capabilities of a malicious coalition of parties attempting to divulge information about client measurements; and¶
Conditions that are necessary to ensure that malicious clients cannot corrupt the computation.¶
Provide cryptographers with design criteria that provide a clear deployment roadmap for new constructions of privacy-preserving measurement systems.¶
This document also specifies two concrete VDAF schemes, each based on a protocol from the literature.¶
The Prio system [CGB17] allows for the privacy-preserving computation of a variety of aggregate statistics, combining additive secret sharing as described above with a mechanism for checking the validity of each measurement. In Section 7 we specify Prio3, a VDAF that follows the same overall framework as the original Prio protocol, but incorporates techniques introduced in [BBCGGI19] that result in significant performance gains.¶
The Poplar protocol [BBCGGI21] solves a problem known as private
heavy-hitters. In this problem, each client holds a bit-string, and the goal
of the aggregation servers is to compute the set of strings that occur at
least T
times for some threshold T
. The core primitive in their protocol
is a secret sharing of a point function [GI14] (denoted G
above) that
allows the servers to privately count how many of the clients' strings begin
with a given prefix (agg_param
in the notation above). In Section 8 we
specify a VDAF called Poplar1 that implements this functionality.¶
The remainder of this document is organized as follows: Section 2 lists definitions and conventions used in the remainder of the document; Section 3 gives a brief overview of DAFs and VDAFs, the parties involved in the computation, and the requirements for non-collusion; Section 4 defines the syntax for DAFs; Section 5 defines the syntax for VDAFs; Section 6 defines various functionalities that are common to our constructions; Section 7 specifies Prio3; Section 8 specifies Poplar1; and Section 9 enumerates security considerations for DAFs and VDAFs in general and our constructions in particular.¶
(RFC EDITOR: remove this section.)¶
(*) Indicates a change that breaks wire compatibility with the previous draft.¶
13:¶
(V)DAF: Replace the one-shot aggregation API with a streaming API. Each Aggregator initializes aggregation, then updates its aggregate share as output shares are produced. The scheme also specifies a method for merging multiple aggregate shares.¶
Poplar1: Move prefix uniqueness and ordering checks from prep_init()
to
is_valid()
.¶
Poplar1: Use bool
to represent control bits instead of Field2
.¶
Prio3MultihotCountVec: Change the measurement type from list[int]
to
list[bool]
.¶
Security considerations: Define our threat model for side channel attacks and enumerate the parts of the spec that are most relevant to implementers.¶
Improve the specification of each Prio3 variant by listing each
implementation of Valid
and Gadget
in full. Gadgets are listed in a new
appendix section.¶
Improve the specification of the FLP system by listing the proof-generation, query, and decision algorithms in full. The wrapper gadgets are listed in the new section of the appendix for gadgets.¶
Add a section with a high-level overview of the IDPF construction.¶
Move some sections around: move ping-pong and star topologies under communication patterns for VDAF preparation; move FLP proof generation, query, and decision algorithms up one level; move privacy considerations for aggregation parameters up one level; and move safe usage of IDPF outputs up one level.¶
12:¶
(V)DAF: Add an application context string parameter to sharding and preparation. The motivation for this change is to harden Prio3 against offline attacks. More generally, however, it allows designing schemes for which correct execution requires agreement on the application context. Accordingly, both Prio3 and Poplar1 have been modified to include the context in the domain separation tag of each XOF invocation. (*)¶
Prio3: Improve soundness of the base proof system and the circuits of some variants. Generally speaking, wherever we evaluate a univariate polynomial at a random point, we can instead evaluate a multivariate polynomial of lower degree. (*)¶
Prio3: Replace the helper's measurement and proof share seeds with a single seed. (*)¶
Prio3Sum: Update the circuit to support a more general range check and avoid using joint randomness. (*)¶
Prio3Histogram, Prio3MultihotCountVec: Move the final reduction of the intermediate outputs out of the circuit. (*)¶
IDPF: Add the application context string to key generation and evaluation and bind it to the fixed AES key. (*)¶
IDPF: Use XofTurboShake128 for deriving the leaf nodes in order to ensure the construction is extractable. (*)¶
IDPF: Simplify the public share encoding. (*)¶
XofTurboShake128: Change SEED_SIZE
from 16 bytes to 32 to mitigate offline
attacks on Prio3 robustness. In addition, allow seeds of different lengths so
that we can continue to use XofTurboShake128 with IDPF. (*)¶
XofTurboShake128, XofFixedKeyAes128: Increase the length prefix for the domain separation tag from one by to two bytes. This is to accommodate the application context. (*)¶
Reassign codepoints for all Prio3 variants and Poplar1. (*)¶
Security considerations: Add a section on defense-in-depth measures taken by Prio3 and Poplar1 and more discussion about choosing FLP parameters.¶
11:¶
Define message formats for the Poplar1 aggregation parameter and IDPF public share.¶
IDPF: Require the IDPF binder must be a random nonce.¶
VDAF: Replace the pseudocode description of the ping-ping topology with Python and sketch the star topology.¶
DAF: Align aggregation parameter validation with VDAF.¶
Replace Union[A, B]
type with A | B
.¶
Rename FFT ("Fast Fourier Transform") with NTT ("Number Theoretic Transform").¶
10:¶
Define Prio3MultihotCountVec, a variant of Prio3 for aggregating bit vectors with bounded weight.¶
FLP: Allow the output of the circuit to be a vector. This makes it possible to skip joint randomness derivation in more cases.¶
Poplar1: On the first round of preparation, handle None
as an error.
Previously this message was interpreted as a length-3 vector of zeros.¶
Prio3: Move specification of the field from the FLP validity circuit to the VDAF itself.¶
Clarify the extent to which the attacker controls the network in our threat models for privacy and robustness.¶
Clean up various aspects of the code, including: Follow existing object-oriented programming patterns for Python more closely; make the type hints enforceable; and avoid shadowing variables.¶
IDPF: Add guidance for encoding byte strings as indices.¶
09:¶
Poplar1: Make prefix tree traversal stricter by requiring each node to be a child of a node that was already visited. This change is intended to make it harder for a malicious Aggregator to steer traversal towards non-heavy-hitting measurements.¶
Prio3: Add more explicit guidance for choosing the field size.¶
IDPF: Define extractability and clarify (un)safe usage of intermediate prefix counts. Accordingly, add text ensuring public share consistency to security considerations.¶
08:¶
Poplar1: Bind the report nonce to the authenticator vector programmed into the IDPF. (*)¶
IdpfPoplar: Modify extend()
by stealing each control bit from its
corresponding seed. This improves performance by reducing the number of AES
calls per level from 3 to 2. The cost is a slight reduction in the concrete
privacy bound. (*)¶
Prio3: Add support for generating and verifying multiple proofs per measurement. This enables a trade-off between communication cost and runtime: if more proofs are used, then a smaller field can be used without impacting robustness. (*)¶
Replace SHAKE128 with TurboSHAKE128. (*)¶
07:¶
Rename PRG to XOF ("eXtendable Output Function"). Accordingly, rename PrgSha3 to XofShake128 and PrgFixedKeyAes128 to XofFixedKeyAes128. "PRG" is a misnomer since we don't actually treat this object as a pseudorandom generator in existing security analysis.¶
Replace cSHAKE128 with SHAKE128, re-implementing domain separation for the customization string using a simpler scheme. This change addresses the reality that implementations of cSHAKE128 are less common. (*)¶
Define a new VDAF, called Prio3SumVec, that generalizes Prio3Sum to a vector of summands.¶
Prio3Histogram: Update the codepoint and use the parallel sum optimization introduced by Prio3SumVec to reduce the proof size. (*)¶
Daf, Vdaf: Rename interface methods to match verbiage in the draft.¶
Daf: Align with Vdaf by adding a nonce to shard()
and prep()
.¶
Vdaf: Have prep_init()
compute the first prep share. This change is
intended to simplify the interface by making the input to prep_next()
not
optional.¶
Prio3: Split sharding into two auxiliary functions, one for sharding with joint randomness and another without. This change is intended to improve readability.¶
Fix bugs in the ping-pong interface discovered after implementing it.¶
06:¶
Vdaf: Define a wrapper interface for preparation that is suitable for the "ping-pong" topology in which two Aggregators exchange messages over a request/response protocol, like HTTP, and take turns executing the computation until input from the peer is required.¶
Prio3Histogram: Generalize the measurement type so that the histogram can be used more easily with discrete domains. (*)¶
Daf, Vdaf: Change the aggregation parameter validation algorithm to take the set of previous parameters rather than a list. (The order of the parameters is irrelevant.)¶
Daf, Vdaf, Idpf: Add parameter RAND_SIZE
that specifies the number of
random bytes consumed by the randomized algorithm (shard()
for Daf and Vdaf
and gen()
for Idpf).¶
05:¶
IdpfPoplar: Replace PrgSha3 with PrgFixedKeyAes128, a fixed-key mode for AES-128 based on a construction from [GKWWY20]. This change is intended to improve performance of IDPF evaluation. Note that the new PRG is not suitable for all applications. (*)¶
Idpf: Add a binder string to the key-generation and evaluation algorithms. This is used to plumb the nonce generated by the Client to the PRG.¶
Plumb random coins through the interface of randomized algorithms. Specifically, add a random input to (V)DAF sharding algorithm and IDPF key-generation algorithm and require implementations to specify the length of the random input. Accordingly, update Prio3, Poplar1, and IdpfPoplar to match the new interface. This change is intended to improve coverage of test vectors.¶
Use little-endian byte-order for field element encoding. (*)¶
Poplar1: Move the last step of sketch evaluation from prep_next()
to
prep_shares_to_prep()
.¶
04:¶
Align security considerations with the security analysis of [DPRS23].¶
Vdaf: Pass the nonce to the sharding algorithm.¶
Vdaf: Rather than allow the application to choose the nonce length, have each implementation of the Vdaf interface specify the expected nonce length. (*)¶
Prg: Split "info string" into two components: the "customization string", intended for domain separation; and the "binder string", used to bind the output to ephemeral values, like the nonce, associated with execution of a (V)DAF.¶
Replace PrgAes128 with PrgSha3, an implementation of the Prg interface based on SHA-3, and use the new scheme as the default. Accordingly, replace Prio3Aes128Count with Prio3Count, Poplar1Aes128 with Poplar1, and so on. SHA-3 is a safer choice for instantiating a random oracle, which is used in the analysis of Prio3 of [DPRS23]. (*)¶
Prio3, Poplar1: Ensure each invocation of the Prg uses a distinct customization string, as suggested by [DPRS23]. This is intended to make domain separation clearer, thereby simplifying security analysis. (*)¶
Prio3: Replace "joint randomness hints" sent in each input share with "joint randomness parts" sent in the public share. This reduces communication overhead when the number of shares exceeds two. (*)¶
Prio3: Bind nonce to joint randomness parts. This is intended to address birthday attacks on robustness pointed out by [DPRS23]. (*)¶
Poplar1: Use different Prg invocations for producing the correlated randomness for inner and leaf nodes of the IDPF tree. This is intended to simplify implementations. (*)¶
Poplar1: Don't bind the candidate prefixes to the verifier randomness. This is intended to improve performance, while not impacting security. According to the analysis of [DPRS23], it is necessary to restrict Poplar1 usage such that no report is aggregated more than once at a given level of the IDPF tree; otherwise, attacks on privacy may be possible. In light of this restriction, there is no added benefit of binding to the prefixes themselves. (*)¶
Poplar1: During preparation, assert that all candidate prefixes are unique and appear in order. Uniqueness is required to avoid erroneously rejecting a valid report; the ordering constraint ensures the uniqueness check can be performed efficiently. (*)¶
Poplar1: Increase the maximum candidate prefix count in the encoding of the aggregation parameter. (*)¶
Poplar1: Bind the nonce to the correlated randomness derivation. This is intended to provide defense-in-depth by ensuring the Aggregators reject the report if the nonce does not match what the Client used for sharding. (*)¶
Poplar1: Clarify that the aggregation parameter encoding is OPTIONAL. Accordingly, update implementation considerations around cross-aggregation state.¶
IdpfPoplar: Add implementation considerations around branching on the values of control bits.¶
IdpfPoplar: When decoding the control bits in the public share, assert that the trailing bits of the final byte are all zero. (*)¶
03:¶
Define codepoints for (V)DAFs and use them for domain separation in Prio3 and Poplar1. (*)¶
Prio3: Align joint randomness computation with revised paper [BBCGGI19]. This change mitigates an attack on robustness. (*)¶
Prio3: Remove an intermediate PRG evaluation from query randomness generation. (*)¶
Add additional guidance for choosing FFT-friendly fields.¶
02:¶
Complete the initial specification of Poplar1.¶
Extend (V)DAF syntax to include a "public share" output by the Client and distributed to all of the Aggregators. This is to accommodate "extractable" IDPFs as required for Poplar1. (See [BBCGGI21], Section 4.3 for details.)¶
Extend (V)DAF syntax to allow the unsharding step to take into account the number of measurements aggregated.¶
Extend FLP syntax by adding a method for decoding the aggregate result from a vector of field elements. The new method takes into account the number of measurements.¶
Prio3: Align aggregate result computation with updated FLP syntax.¶
Prg: Add a method for statefully generating a vector of field elements.¶
Field: Require that field elements are fully reduced before decoding. (*)¶
Define new field Field255.¶
01:¶
Require that VDAFs specify serialization of aggregate shares.¶
Define Distributed Aggregation Functions (DAFs).¶
Prio3: Move proof verifier check from prep_next()
to
prep_shares_to_prep()
. (*)¶
Remove public parameter and replace verification parameter with a "verification key" and "Aggregator ID".¶
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.¶
Algorithms in this document are written in Python (compatible with Python 3.12 or later). A fatal error in a program (e.g., failure to parse one of the function parameters) is usually handled by raising an exception.¶
In Python, array indexing starts with 0
, e.g., x[0]
is the first element
and x[len(x)-1]
is the last of x
. We can also index from the end of the
list, e.g., x[-1]
is the last element of x
.¶
Exponentiation is denoted by x ** y
in Python. We also sometimes use more
conventional notation for exponentiation, namely x^y
.¶
Division of x
by y
is denoted by x / y
. Python includes a similar
operator, x // y
, which is short for floor(x / y)
.¶
Type hints are used to define input and output types:¶
The type variable F
is used in signatures to signify any type that is a
subclass of Field
(Section 6.1).¶
bytes
is a byte string.¶
int
is an integer.¶
Generic
is used in class definitions to explicitly declare type variables
of generic classes.¶
Any
is the universal supertype, which admits values of any type.¶
Optional[T]
is shorthand for T | None
. Its value may be None
or have
type T
.¶
Self
represents the containing class of the method definition in which it
appears.¶
Sequence[T]
is either a list or tuple of values of type T
.¶
This document defines several byte-string constants. When comprised of printable
ASCII characters, they are written as Python 3 byte-string literals (e.g.,
b'some constant string'
).¶
A global constant VERSION
of type int
is defined, which algorithms are free
to use as desired. Its value SHALL be 12
.¶
This document describes algorithms for multi-party computations in which the parties typically communicate over a network. Wherever a quantity is defined that must be transmitted from one party to another, this document prescribes a particular encoding of that quantity as a byte string.¶
Some common functionalities:¶
additive_secret_share(x: list[F], num_shares: int, field: type[F]) ->
list[list[F]]
takes a vector x
of field elements and returns num_shares
vectors of length len(x)
such that they all add up to the input vector.
Note that this function is not used normatively in this document.¶
byte(x: int) -> bytes
returns the representation of the integer x
in the
range [0, 256)
as a single-byte byte string.¶
cast(typ: type[T], x: object) -> T
returns the input value unchanged.
This is only present to assist with static analysis of the Python code.
Type checkers will ignore the inferred type of the input value, and assume
the output value has the given type.¶
concat(parts: list[bytes]) -> bytes
returns the concatenation of the input
byte strings, i.e., parts[0] + ... + parts[len(parts)-1]
.¶
from_be_bytes(encoded: bytes) -> int
decodes a big-endian byte string,
i.e., returns the integer x
for which to_be_bytes(x, len(encoded)) ==
encoded
.¶
from_le_bytes(encoded: bytes) -> int
decodes a little-endian byte string,
i.e., returns the integer x
for which to_le_bytes(x, len(encoded)) ==
encoded
.¶
front(len: int, x: list[Any]) -> tuple[list[Any], list[Any]]
splits x
into two vectors, where the first vector is made up of the first len
elements of x
and the second is made up of the remaining elements. This
function is equivalent to (x[:len], x[len:])
.¶
gen_rand(len: int) -> bytes
returns a byte array of the requested length
(len
) generated by a cryptographically secure pseudorandom number generator
(CSPRNG).¶
next_power_of_2(x: int) -> int
returns the smallest integer
greater than or equal to x
that is also a power of two.¶
range(stop: int)
or range(start: int, stop: int[, step: int])
is the range
function from the Python standard library. The one-argument form returns the
integers from zero (inclusive) to stop
(exclusive). The two- and
three-argument forms allow overriding the start of the range and overriding
the step between successive output values.¶
to_be_bytes(x: int, len: int) -> bytes
converts an integer x
whose value
is in the range [0, 2^(8*len))
to a big-endian byte string of length len
.¶
to_le_bytes(x: int, len: int) -> bytes
converts an integer x
whose value
is in the range [0, 2^(8*len))
to a little-endian byte string of length
len
.¶
poly_eval(field: type[F], p: list[F], x: F) -> F
returns the result of
evaluating the polynomial, p(x)
. The coefficients of polynomials are stored
in lists in ascending order of degree, starting with the constant
coefficient. The field
parameter is the class object for F
and is used by
the implementation to construct field elements. (See Section 6.1.)¶
poly_interp(field: type[F], inputs: list[F], outputs: list[F]) -> list[F]
returns the coefficients of the lowest degree polynomial p
for which
p(inputs[k]) == outputs[k]
for all k
. Normally this will be computed
using the Number Theoretic Transform (NTT) [SML24].¶
poly_mul(field: type[F], p: list[F], q: list[F]) -> list[F]
returns
the product of two polynomials.¶
poly_strip(field: type[F], p: list[F]) -> list[F]
strips the zeros from the
end of the input polynomial's list of coefficients. That is, it returns
p[:i]
where i
is the index of the highest-degree non-zero coefficient of
p
.¶
xor(left: bytes, right: bytes) -> bytes
returns the bitwise XOR of left
and right
. An exception is raised if the inputs are not the same length.¶
zeros(len: int) -> bytes
returns an array of bytes of the requested
length (len
). Each element of the array is set to zero.¶
In a DAF- or VDAF-based private measurement system, we distinguish between three types of actors: Clients, Aggregators, and the Collector. The overall flow of the measurement process is as follows:¶
To submit an individual measurement, the Client shards the measurement into "input shares" and sends one input share to each Aggregator. We sometimes refer to this sequence of input shares collectively as the Client's "report".¶
The Aggregators refine their input shares into "output shares":¶
Output shares are in one-to-one correspondence with the input shares.¶
Just as each Aggregator receives one input share of each measurement, if this process succeeds, then each aggregator holds one output share.¶
In VDAFs, Aggregators will need to exchange information among themselves as part of the validation process.¶
As each Aggregator recovers output shares, it accumulates them into an "aggregate share" for the batch of measurements.¶
The Aggregators submit their aggregate shares to the Collector, who combines them to obtain the aggregate result over the batch.¶
Aggregators are a new class of actor relative to traditional measurement systems where Clients submit measurements to a single server. They are critical for both the privacy properties of the system and, in the case of VDAFs, the validity of the aggregate results obtained. The privacy properties of the system are assured by non-collusion among Aggregators, and Aggregators are the entities that perform validation of Client measurements. Thus Clients trust Aggregators not to collude (typically it is required that at least one Aggregator is honest; see Section 9.8), and Collectors trust Aggregators to correctly run the protocol.¶
Within the bounds of the non-collusion requirements of a given (V)DAF instance, it is possible for the same entity to play more than one role. For example, the Collector could also act as an Aggregator, effectively using the other Aggregator(s) to augment a basic client-server protocol.¶
In this document, we describe the computations performed by the actors in this system. It is up to the higher-level protocol making use of the (V)DAF to arrange for the required information to be delivered to the proper actors in the proper sequence. In general, we assume that all communications are confidential and mutually authenticated, with the exception that Clients submitting measurements may be anonymous.¶
By way of a gentle introduction to VDAFs, this section describes a simpler class of schemes called Distributed Aggregation Functions (DAFs). Unlike VDAFs, DAFs do not provide verifiability of the computation. Clients must therefore be trusted to compute their input shares correctly. Because of this fact, the use of a DAF is NOT RECOMMENDED for most applications. See Section 9 for additional discussion.¶
A DAF scheme is used to compute a particular "aggregation function" over a set of measurements generated by Clients. Depending on the aggregation function, the Collector might select an "aggregation parameter" and disseminate it to the Aggregators. The semantics of this parameter is specific to the aggregation function, but in general it is used to represent the set of "queries" that can be made by the Collector on the batch of measurements. For example, the aggregation parameter is used to represent the candidate prefixes in the Poplar1 VDAF (Section 8).¶
Execution of a DAF has four distinct stages:¶
Sharding: Each Client generates input shares from its measurement and distributes them among the Aggregators. In addition to the input shares, the client generates a "public share" during this step that is disseminated to all of the Aggregators.¶
Preparation: Each Aggregator converts each input share into an output share compatible with the aggregation function. This computation involves the aggregation parameter. In general, each aggregation parameter may result in a different output share.¶
Aggregation: Each Aggregator combines a sequence of output shares into its aggregate share and sends the aggregate share to the Collector.¶
Unsharding: The Collector combines the aggregate shares into the aggregate result.¶
Sharding and preparation are done once per measurement. Aggregation and unsharding are done over a batch of measurements (more precisely, over the recovered output shares).¶
A concrete DAF specifies the algorithm for the computation needed in each of
these stages. The interface, denoted Daf
, is defined in the remainder of this
section. In addition, a concrete DAF defines the associated constants and types
enumerated in the following table.¶
Parameter | Description |
---|---|
ID: int
|
Algorithm identifier for this DAF, in the range [0, 2^32) . |
SHARES: int
|
Number of input shares into which each measurement is sharded. |
NONCE_SIZE: int
|
Size of the nonce associated with the report. |
RAND_SIZE: int
|
Size of the random byte string consumed by the sharding algorithm. |
Measurement
|
Type of each measurement. |
PublicShare
|
Type of each public share. |
InputShare
|
Type of each input share. |
AggParam
|
Type of the aggregation parameter. |
OutShare
|
Type of each output share. |
AggShare
|
Type of the aggregate share. |
AggResult
|
Type of the aggregate result. |
The types in this table define the inputs and outputs of DAF methods at various
stages of the computation. Some of these values need to be written to the
network in order to carry out the computation. In particular, it is RECOMMENDED
that concrete instantiations of the Daf
interface specify a standard encoding
for the PublicShare
, InputShare
, AggParam
, and AggShare
types.¶
The sharding algorithm run by each Client is defined as follows:¶
daf.shard(ctx: bytes, measurement: Measurement, nonce: bytes, rand: bytes)
-> tuple[PublicShare, list[InputShare]]
consumes the "application context"
(defined below), a measurement, and a nonce and produces the public share,
distributed to each of the Aggregators, and the input shares, one for each
Aggregator.¶
Pre-conditions:¶
nonce
MUST have length equal to daf.NONCE_SIZE
and MUST be generated
using a cryptographically secure random number generator (CSPRNG).¶
rand
consists of the random bytes consumed by the algorithm. It MUST have
length equal to daf.RAND_SIZE
and MUST be generated using a CSPRNG.¶
Post-conditions:¶
The number of input shares MUST equal daf.SHARES
.¶
Sharding is bound to a specific "application context". The application context is a string intended to uniquely identify an instance of the higher level protocol that uses the DAF. The goal of binding the application to DAF execution is to ensure that aggregation succeeds only if the Clients and Aggregators agree on the application context. (Preparation binds the application context, too; see Section 4.2.) Note that, unlike VDAFs (Section 5), there is no explicit signal of disagreement; it may only manifest as a garbled aggregate result.¶
The nonce is a public random value associated with the report. It is referred to as a nonce because normally it will also be used as a unique identifier for that report in the context of some application. The randomness requirement is especially important for VDAFs, where it may be used by the Aggregators to derive per-report randomness for verification of the computation. See Section 9.2 for details.¶
Once an Aggregator has received the public share and its input share, the next step is to prepare the input share for aggregation. This is accomplished using the preparation algorithm:¶
daf.prep(ctx: bytes, agg_id: int, agg_param: AggParam, nonce: bytes,
public_share: PublicShare, input_share: InputShare) -> OutShare
consumes the
public share and one of the input shares generated by the Client, the
application context, the Aggregator's unique identifier, the aggregation
parameter selected by the Collector, and the report nonce and returns an
output share.¶
Pre-conditions:¶
The Aggregators MUST agree on the value of the aggregation parameter. Otherwise, the aggregate result may be computed incorrectly by the Collector.¶
In general, it is permissible to aggregate a batch of reports multiple times. However, to prevent privacy violations, DAFs may impose certain restrictions on the aggregation parameters selected by the Collector. Restrictions are expressed by the aggregation parameter validity function:¶
daf.is_valid(agg_param: AggParam, previous_agg_params: list[AggParam]) ->
bool
returns True
if agg_param
is allowed given the sequence
previous_agg_params
of previously accepted aggregation parameters.¶
Prior to accepting an aggregation parameter from the Collector and beginning preparation, each Aggregator MUST validate it using this function.¶
Once an Aggregator holds an output share, it adds it into its aggregate share for the batch. This streaming aggregation process is implemented by the following pair of algorithms:¶
daf.agg_init(agg_param: AggParam) -> AggShare
returns an empty aggregate
share. It is called to initialize aggregation of a batch of measurements.¶
daf.agg_update(agg_param: AggParam, agg_share: AggShare, out_share:
OutShare) -> AggShare
accumulates an output share into an aggregate share
and returns the updated aggregate share.¶
In many situations it is desirable to split an aggregate share across multiple storage elements, then merge the aggregate shares together just before releasing the completed aggregate share to the Collector. DAFs facilitate this with the following method:¶
daf.merge(agg_param: AggParam, agg_shares: list[AggShare]) -> AggShare
merges a sequence of aggregate shares into a single aggregate share.¶
For most DAFs and VDAFs, the outcome of aggregation is not sensitive to the order in which output shares are aggregated. This means that aggregate shares can be updated or merged with other aggregate shares in any order. For instance, for both Prio3 (Section 7) and Poplar1 (Section 8), the aggregate shares and output shares both have the same type, a vector over some finite field (Section 6.1); and aggregation involves simply adding vectors together.¶
In theory, however, there may be a DAF or VDAF for which correct execution requires each Aggregator to aggregate output shares in the same order.¶
After the Aggregators have aggregated all measurements in the batch, each sends its aggregate share to the Collector, who runs the unsharding algorithm to recover the aggregate result:¶
Secure execution of a DAF involves simulating the following procedure over an insecure network.¶
def run_daf( daf: Daf[ Measurement, AggParam, PublicShare, InputShare, OutShare, AggShare, AggResult, ], ctx: bytes, agg_param: AggParam, measurements: list[Measurement]) -> AggResult: agg_shares: list[AggShare] agg_shares = [daf.agg_init(agg_param) for _ in range(daf.SHARES)] for measurement in measurements: # Sharding nonce = gen_rand(daf.NONCE_SIZE) rand = gen_rand(daf.RAND_SIZE) (public_share, input_shares) = \ daf.shard(ctx, measurement, nonce, rand) # Preparation, aggregation for j in range(daf.SHARES): out_share = daf.prep(ctx, j, agg_param, nonce, public_share, input_shares[j]) agg_shares[j] = daf.agg_update(agg_param, agg_shares[j], out_share) # Unsharding num_measurements = len(measurements) agg_result = daf.unshard(agg_param, agg_shares, num_measurements) return agg_result¶
The inputs to this procedure include the parameters of the aggregation function computed by the DAF: an aggregation parameter and a sequence of measurements. They also include the application context. The procedure prescribes how a DAF is executed in a "benign" environment in which there is no adversary and the messages are passed among the protocol participants over secure point-to-point channels. In reality, these channels need to be instantiated by some "wrapper protocol", such as [DAP], that realizes these channels using suitable cryptographic mechanisms. Moreover, some fraction of the Aggregators (or Clients) may be malicious and diverge from their prescribed behaviors. Section 9 describes the execution of the DAF in various adversarial environments and what properties the wrapper protocol needs to provide in each.¶
VDAFs are identical to DAFs except that preparation is an interactive process carried out by the Aggregators. If successful, this process results in each Aggregator computing an output share. The process will fail if, for example, the underlying measurement is invalid.¶
Failure manifests as an exception raised by one of the algorithms defined in this section. If an exception is raised during preparation, the Aggregators MUST remove the report from the batch and not attempt to aggregate it. Otherwise, a malicious Client can cause the Collector to compute a malformed aggregate result.¶
The remainder of this section defines the VDAF interface, which we denote by
Vdaf
. The attributes listed in Table 2 are defined by each concrete
VDAF.¶
Parameter | Description |
---|---|
ID: int
|
Algorithm identifier for this VDAF, in the range [0, 2^32) . |
SHARES: int
|
Number of input shares into which each measurement is sharded. |
ROUNDS: int
|
Number of rounds of communication during preparation. |
NONCE_SIZE: int
|
Size of the report nonce. |
RAND_SIZE: int
|
Size of the random byte string consumed during sharding. |
VERIFY_KEY_SIZE: int
|
Size of the verification key used during preparation. |
Measurement
|
Type of each measurement. |
PublicShare
|
Type of each public share. |
InputShare
|
Type of each input share. |
AggParam
|
Type of the aggregation parameter. |
OutShare
|
Type of each output share. |
AggShare
|
Type of the aggregate share. |
AggResult
|
Type of the aggregate result. |
PrepState
|
Type of the prep state. |
PrepShare
|
Type of each prep share. |
PrepMessage
|
Type of each prep message. |
Some of the types in the table above need to be written to the network in
order to carry out the computation. It is RECOMMENDED that concrete
instantiations of the Vdaf
interface specify a method of encoding the
PublicShare
, InputShare
, AggParam
, AggShare
, PrepShare
, and
PrepMessage
types.¶
Each VDAF is identified by a unique 32-bit integer, denoted ID
. Identifiers
for each VDAF specified in this document are defined in Table 18. The
following method is used by both Prio3 and Poplar1:¶
def domain_separation_tag(self, usage: int, ctx: bytes) -> bytes: """ Format domain separation tag for this VDAF with the given application context and usage. Pre-conditions: - `usage` in the range `[0, 2^16)` """ return format_dst(0, self.ID, usage) + ctx¶
The output, called the "domain separation tag", is used in our constructions
for domain separation. Function format_dst()
is defined in Section 6.2.3.¶
Sharding is as described for DAFs in Section 4.1. The public share and input shares encode additional information used during preparation to validate the output shares before they are aggregated (e.g., the "proof shares" in Section 7).¶
Like DAFs, sharding is bound to the application context via the application context string. Again, this is intended to ensure that aggregation succeeds only if the Clients and Aggregators agree on the application context. Unlike DAFs, however, disagreement on the context should manifest as a preparation failure, causing the report to be rejected without garbling the aggregate result. The application context also provides some defense-in-depth against cross protocol attacks; see Section 9.9.¶
Preparation is organized into a number of rounds. The number of rounds depends on the VDAF: Prio3 (Section 7) has one round and Poplar1 (Section 8) has two.¶
Aggregators retain some local state between successive rounds of preparation. This is referred to as "preparation state" or "prep state" for short.¶
During each round, each Aggregator broadcasts a message called a "preparation share", or "prep share" for short. The prep shares are then combined into a single message called the "preparation message", or "prep message". The prep message MAY be computed by any one of the Aggregators.¶
The prep message is disseminated to each of the Aggregators to begin the next round. An Aggregator begins the first round with its input share and it begins each subsequent round with the current prep state and the previous prep message. Its output in the last round is its output share and its output in each of the preceding rounds is a prep share.¶
Just as for DAFs (Section 4.2), preparation involves an aggregation parameter. The aggregation parameter is consumed by each Aggregator before the first round of communication.¶
Unlike DAFs, VDAF preparation involves a secret "verification key" held by each of the Aggregators. This key is used to verify validity of the output shares they compute. It is up to the high level protocol in which the VDAF is used to arrange for the distribution of the verification key prior to generating and processing reports. See Section 9 for details.¶
Preparation is implemented by the following set of algorithms:¶
vdaf.prep_init(verify_key: bytes, ctx: bytes, agg_id: int, agg_param:
AggParam, nonce: bytes, public_share: PublicShare, input_share: InputShare)
-> tuple[PrepState, PrepShare]
is the deterministic preparation state
initialization algorithm run by each Aggregator. It consumes the shared
verification key, the application context, the Aggregator's unique
identifier, the aggregation parameter chosen by the Collector, the report
nonce, the public share, and one of the input shares generated by the Client.
It produces the Aggregator's initial prep state and prep share.¶
Protocols MUST ensure that public share consumed by each of the Aggregators is identical. This is security critical for VDAFs such as Poplar1.¶
Pre-conditions:¶
vdaf.prep_shares_to_prep(ctx: bytes, agg_param: AggParam, prep_shares:
list[PrepShare]) -> PrepMessage
is the deterministic preparation message
pre-processing algorithm. It combines the prep shares produced by the
Aggregators in the previous round into the prep message consumed by each
Aggregator to start the next round.¶
vdaf.prep_next(ctx: bytes, prep_state: PrepState, prep_msg: PrepMessage) ->
tuple[PrepState, PrepShare] | OutShare
is the deterministic
preparation state update algorithm run by each Aggregator. It updates the
Aggregator's prep state (prep_state
) and returns either its next prep state
and prep share for the next round or, if this is the last round, its output
share.¶
An exception may be raised by one of these algorithms, in which case the report MUST be deemed invalid and not processed any further.¶
Implementation note: The preparation process accomplishes two tasks: recovery of output shares from the input shares and ensuring that the recovered output shares are valid. The abstraction boundary is drawn so that an Aggregator only recovers an output share if the underlying data is deemed valid (at least, based on the Aggregator's view of the protocol). Another way to draw this boundary would be to have the Aggregators recover output shares first, then verify that they are valid. However, this would allow the possibility of misusing the API by, say, aggregating an invalid output share. Moreover, in protocols like Prio+ [AGJOP21] based on oblivious transfer, it is necessary for the Aggregators to interact in order to recover aggregatable output shares at all.¶
Aggregation parameter validation is as described for DAFs in Section 4.3. Again, each Aggregator MUST validate each aggregation parameter received from the Collector before beginning preparation with that parameter.¶
Aggregation is identical to DAF aggregation as described in Section 4.4. As with DAFs, computation of the VDAF aggregate is not usually sensitive to the order in which output shares are aggregated. See Section 4.4.1.¶
Unsharding is identical to DAF unsharding as described in Section 4.5.¶
Secure execution of a VDAF involves simulating the following procedure over an insecure network.¶
def run_vdaf( vdaf: Vdaf[ Measurement, AggParam, PublicShare, InputShare, list[F], # OutShare AggShare, AggResult, PrepState, PrepShare, PrepMessage, ], verify_key: bytes, agg_param: AggParam, ctx: bytes, measurements: list[Measurement]) -> AggResult: """ Pre-conditions: - `len(verify_key) == vdaf.VERIFY_KEY_SIZE` """ agg_shares = [vdaf.agg_init(agg_param) for _ in range(vdaf.SHARES)] for measurement in measurements: # Sharding nonce = gen_rand(vdaf.NONCE_SIZE) rand = gen_rand(vdaf.RAND_SIZE) (public_share, input_shares) = \ vdaf.shard(ctx, measurement, nonce, rand) # Initialize preparation prep_states = [] outbound_prep_shares = [] for j in range(vdaf.SHARES): (state, share) = vdaf.prep_init(verify_key, ctx, j, agg_param, nonce, public_share, input_shares[j]) prep_states.append(state) outbound_prep_shares.append(share) # Complete preparation for i in range(vdaf.ROUNDS - 1): prep_msg = vdaf.prep_shares_to_prep(ctx, agg_param, outbound_prep_shares) outbound_prep_shares = [] for j in range(vdaf.SHARES): out = vdaf.prep_next(ctx, prep_states[j], prep_msg) assert isinstance(out, tuple) (prep_states[j], prep_share) = out outbound_prep_shares.append(prep_share) prep_msg = vdaf.prep_shares_to_prep(ctx, agg_param, outbound_prep_shares) # Aggregation for j in range(vdaf.SHARES): out_share = vdaf.prep_next(ctx, prep_states[j], prep_msg) assert not isinstance(out_share, tuple) agg_shares[j] = vdaf.agg_update(agg_param, agg_shares[j], out_share) # Unsharding num_measurements = len(measurements) agg_result = vdaf.unshard(agg_param, agg_shares, num_measurements) return agg_result¶
The inputs to this algorithm are the verification key, application context, aggregation parameter, and a list of measurements. As explained in Section 4.6, the secure execution of a VDAF requires the application to instantiate secure channels between each of the protocol participants.¶
The only stage of VDAF execution that requires interaction is preparation
(Section 5.2). There are a number of ways to coordinate this
interaction; the best strategy depends largely on the number of Aggregators
(i.e., vdaf.SHARES
). This section describes two strategies, one specialized
for two Aggregators and another that is suitable for any number of Aggregators.¶
In each round of preparation, each Aggregator writes a prep share to some
broadcast channel, which is then processed into the prep message using the
public prep_shares_to_prep()
algorithm and broadcast to the Aggregators to
start the next round. Our goal in this section is to realize this broadcast
channel.¶
The state machine of each Aggregator is shown below.¶
State transitions are made when the state is acted upon by the Aggregator's
local inputs and/or messages sent by its co-Aggregators. The initial state is
Start
. The terminal states are: Rejected
, indicating that the report cannot
be processed any further; and Finished(out_share)
, indicating that the
Aggregator has recovered an output share out_share
. For completeness, we
define these states in Appendix B.¶
The methods described in this section are defined in terms of opaque byte
strings. A compatible Vdaf
MUST specify methods for encoding public shares,
input shares, prep shares, prep messages, and aggregation parameters.¶
Implementations of Prio3 and Poplar1 MUST use the encoding schemes specified in Section 7.2.7 and Section 8.2.6 respectively.¶
For VDAFs with precisely two Aggregators (i.e., vdaf.SHARES == 2
), the
following "ping pong" communication pattern can be used. It is compatible with
any request/response transport protocol, such as HTTP.¶
Let us call the initiating Aggregator the "Leader" and the responding Aggregator the "Helper". The high-level idea is that the Leader and Helper will take turns running the computation locally until input from their peer is required:¶
For a 1-round VDAF (e.g., Prio3 in Section 7), the Leader sends its prep share to the Helper, who computes the prep message locally, computes its output share, then sends the prep message to the Leader. Preparation requires just one round trip between the Leader and the Helper.¶
For a 2-round VDAF (e.g., Poplar1 in Section 8), the Leader sends its first-round prep share to the Helper, who replies with the first-round prep message and its second-round prep share. In the next request, the Leader computes its second-round prep share locally, computes its output share, and sends the second-round prep message to the Helper. Finally, the Helper computes its own output share.¶
In general, each request includes the Leader's prep share for the previous round and/or the prep message for the current round; correspondingly, each response consists of the prep message for the current round and the Helper's prep share for the next round.¶
The Aggregators proceed in this ping-ponging fashion until a step of the
computation fails (indicating the report is invalid and should be rejected) or
preparation is completed. All told there are ceil((vdaf.ROUNDS+1)/2)
requests sent.¶
We specify protocol messages in the presentation language of TLS; see Section 3 of [RFC8446]. Each message is structured as follows:¶
enum { initialize(0), continue(1), finish(2), (255) } MessageType; struct { MessageType type; select (Message.type) { case initialize: opaque prep_share<0..2^32-1>; case continue: opaque prep_msg<0..2^32-1>; opaque prep_share<0..2^32-1>; case finish: opaque prep_msg<0..2^32-1>; }; } Message;¶
These messages trigger all transitions in the state machine in
Figure 7, except for the Leader's initial transition. The
Leader's state is initialized using its local inputs with the following method
on class Vdaf
:¶
def ping_pong_leader_init( self, vdaf_verify_key: bytes, ctx: bytes, agg_param: bytes, nonce: bytes, public_share: bytes, input_share: bytes) -> tuple[State, Optional[bytes]]: """Called by the Leader to initialize ping-ponging.""" try: (prep_state, prep_share) = self.prep_init( vdaf_verify_key, ctx, 0, self.decode_agg_param(agg_param), nonce, self.decode_public_share(public_share), self.decode_input_share(0, input_share), ) encoded_prep_share = self.encode_prep_share(prep_share) return ( Continued(prep_state, 0), encode(0, encoded_prep_share), # initialize ) except: return (Rejected(), None)¶
The output is the State
to which the Leader has transitioned and an encoded
Message
. If the Leader's state is Rejected
, then processing halts.
Otherwise, if the state is Continued
, then processing continues. The function
encode
is used to encode the outbound message, which has the message type of
initialize
(identified by the number 0
).¶
To continue processing the report, the Leader sends the outbound message to the Helper. The Helper's initial transition is computed using the following procedure:¶
def ping_pong_helper_init( self, vdaf_verify_key: bytes, ctx: bytes, agg_param: bytes, nonce: bytes, public_share: bytes, input_share: bytes, inbound: bytes) -> tuple[State, Optional[bytes]]: """ Called by the Helper in response to the Leader's initial message. """ try: (prep_state, prep_share) = self.prep_init( vdaf_verify_key, ctx, 1, self.decode_agg_param(agg_param), nonce, self.decode_public_share(public_share), self.decode_input_share(1, input_share), ) (inbound_type, inbound_items) = decode(inbound) if inbound_type != 0: # initialize return (Rejected(), None) encoded_prep_share = inbound_items[0] prep_shares = [ self.decode_prep_share(prep_state, encoded_prep_share), prep_share, ] return self.ping_pong_transition( ctx, self.decode_agg_param(agg_param), prep_shares, prep_state, 0, ) except: return (Rejected(), None)¶
The procedure decode()
decodes the inbound message and returns the
MessageType variant (initialize
, continue
, or finish
) and the fields of
the message. The procedure ping_pong_transition()
takes in the prep shares,
combines them into the prep message, and computes the next prep state of the
caller:¶
def ping_pong_transition( self, ctx: bytes, agg_param: AggParam, prep_shares: list[PrepShare], prep_state: PrepState, prep_round: int) -> tuple[State, bytes]: prep_msg = self.prep_shares_to_prep(ctx, agg_param, prep_shares) encoded_prep_msg = self.encode_prep_msg(prep_msg) out = self.prep_next(ctx, prep_state, prep_msg) if prep_round+1 == self.ROUNDS: return ( Finished(out), encode(2, encoded_prep_msg), # finalize ) (prep_state, prep_share) = cast( tuple[PrepState, PrepShare], out) encoded_prep_share = self.encode_prep_share(prep_share) return ( Continued(prep_state, prep_round+1), encode(1, encoded_prep_msg, encoded_prep_share) # continue )¶
The output is the State
to which the Helper has transitioned and an encoded
Message
. If the Helper's state is Finished
or Rejected
, then processing
halts. Otherwise, if the state is Continued
, then processing continues.¶
To continue processing, the Helper sends the outbound message to the Leader.
The Leader computes its next state transition using the following method on
class Vdaf
:¶
def ping_pong_leader_continued( self, ctx: bytes, agg_param: bytes, state: State, inbound: bytes, ) -> tuple[State, Optional[bytes]]: """ Called by the Leader to start the next step of ping-ponging. """ return self.ping_pong_continued( True, ctx, agg_param, state, inbound) def ping_pong_continued( self, is_leader: bool, ctx: bytes, agg_param: bytes, state: State, inbound: bytes, ) -> tuple[State, Optional[bytes]]: try: if not isinstance(state, Continued): return (Rejected(), None) prep_round = state.prep_round (inbound_type, inbound_items) = decode(inbound) if inbound_type == 0: # initialize return (Rejected(), None) encoded_prep_msg = inbound_items[0] prep_msg = self.decode_prep_msg( state.prep_state, encoded_prep_msg, ) out = self.prep_next(ctx, state.prep_state, prep_msg) if prep_round+1 < self.ROUNDS and \ inbound_type == 1: # continue (prep_state, prep_share) = cast( tuple[PrepState, PrepShare], out) encoded_prep_share = inbound_items[1] prep_shares = [ self.decode_prep_share( prep_state, encoded_prep_share, ), prep_share, ] if is_leader: prep_shares.reverse() return self.ping_pong_transition( ctx, self.decode_agg_param(agg_param), prep_shares, prep_state, prep_round+1, ) elif prep_round+1 == self.ROUNDS and \ inbound_type == 2: # finish return (Finished(out), None) else: return (Rejected(), None) except: return (Rejected(), None)¶
If the Leader's state is Finished
or Rejected
, then processing halts.
Otherwise, the Leader sends the outbound message to the Helper. The Helper
computes its next state transition using the following method on class Vdaf
:¶
def ping_pong_helper_continued( self, ctx: bytes, agg_param: bytes, state: State, inbound: bytes, ) -> tuple[State, Optional[bytes]]: """Called by the Helper to continue ping-ponging.""" return self.ping_pong_continued( False, ctx, agg_param, state, inbound)¶
They continue in this way until processing halts. Note that, depending on the
number of rounds of preparation that are required, when one party reaches the
Finished
state, there may be one more message to send before the peer can
also finish processing (i.e., the outbound message is not None
).¶
The ping-pong topology of the previous section is only suitable for applications of VDAFs involving exactly two Aggregators. In applications with more than two Aggregators, the star topology described in this section can be used instead.¶
We again designate an Aggregator to initiate the computation. We refer to this Aggregator as the Leader and to all other Aggregators as Helpers.¶
At the start of each round, the Leader requests from each Helper its prep
share. After gathering each of the prep shares, the Leader computes the next
prep message (via vdaf.prep_shares_to_prep()
) and broadcasts it to the
Helpers. At this point, each Aggregator runs vdaf.prep_next()
locally to
either recover an output share or, if more rounds of preparation are required,
compute its updated state and prep share. If another round is required, then
the Helper responds to the broadcast message with its next prep share.¶
The Aggregators proceed in this way until each recovers an output share or some step of the computation fails.¶
This section describes the primitives that are common to the VDAFs specified in this document.¶
Both Prio3 and Poplar1 use finite fields of prime order. Finite field
elements are represented by a class Field
with the following associated
parameters:¶
MODULUS: int
is the prime modulus that defines the field.¶
ENCODED_SIZE: int
is the number of bytes used to encode a field element
as a byte string.¶
Concrete fields, i.e., subclasses of Field
, implement the following class
methods:¶
Field.zeros(length: int) -> list[Self]
returns a vector of zeros of the
requested length.¶
Pre-conditions:¶
length
MUST be greater than or equal 0
.¶
Post-conditions:¶
The length of the output MUST be length
.¶
Field.rand_vec(length: int) -> list[Self]
returns a vector of random field
elements and has the same pre- and post-conditions as for Field.zeros()
.
Note that this function is not used normatively in the specification of
either Prio3 or Poplar1.¶
A field element is an instance of a concrete Field
. Addition,
subtraction, multiplication, division, negation, and inversion are denoted,
respectively, x + y
, x - y
, x * y
, x / y
, -x
, and x.inv()
.¶
We sometimes need to convert a field element to an int
, which we denote by
x.int()
. Likewise, each concrete Field
implements a constructor for
converting an integer into a field element:¶
Field(integer: int)
returns integer
represented as a field element. The
value of integer
MUST be in the range (-Field.MODULUS, Field.MODULUS)
;
negative values are treated as negations.¶
The following class methods on Field
are used to encode and decode vectors of
field elements as byte strings:¶
def encode_vec(cls, vec: list[Self]) -> bytes: """ Encode a vector of field elements `vec` as a byte string. """ encoded = bytes() for x in vec: encoded += to_le_bytes(x.int(), cls.ENCODED_SIZE) return encoded def decode_vec(cls, encoded: bytes) -> list[Self]: """ Parse a vector of field elements from `encoded`. """ if len(encoded) % cls.ENCODED_SIZE != 0: raise ValueError( 'input length must be a multiple of the size of an ' 'encoded field element') vec = [] while len(encoded) > 0: (encoded_x, encoded) = front(cls.ENCODED_SIZE, encoded) x = from_le_bytes(encoded_x) if x >= cls.MODULUS: raise ValueError('modulus overflow') vec.append(cls(x)) return vec¶
Field
provides the following class methods for representing an integer as a
sequence of field elements, each of which represents a bit of the input. These
are used to encode measurements in some variants of Prio3
(Section 7.4).¶
def encode_into_bit_vec( cls, val: int, bits: int) -> list[Self]: """ Encode the bit representation of `val` with at most `bits` number of bits, as a vector of field elements. Pre-conditions: - `val >= 0` - `bits >= 0` """ if val >= 2 ** bits: # Sanity check we are able to represent `val` with `bits` # number of bits. raise ValueError("Number of bits is not enough to represent " "the input integer.") encoded = [] for l in range(bits): encoded.append(cls((val >> l) & 1)) return encoded def decode_from_bit_vec(cls, vec: list[Self]) -> Self: """ Decode the field element from the bit representation, expressed as a vector of field elements `vec`. This may also be used with secret shares of a bit representation, since it is linear. """ bits = len(vec) if cls.MODULUS >> bits == 0: raise ValueError("Number of bits is too large to be " "represented by field modulus.") decoded = cls(0) for (l, bit) in enumerate(vec): decoded += cls(1 << l) * bit return decoded¶
Finally, the following functions define arithmetic on vectors over a finite field. Note that an exception is raised by each function if the operands are not the same length.¶
def vec_sub(left: list[F], right: list[F]) -> list[F]: """ Subtract the right operand from the left and return the result. """ if len(left) != len(right): raise ValueError("mismatched vector sizes") return list(map(lambda x: x[0] - x[1], zip(left, right))) def vec_add(left: list[F], right: list[F]) -> list[F]: """Add the right operand to the left and return the result.""" if len(left) != len(right): raise ValueError("mismatched vector sizes") return list(map(lambda x: x[0] + x[1], zip(left, right))) def vec_neg(vec: list[F]) -> list[F]: """Negate the input vector.""" return list(map(lambda x: -x, vec))¶
Some VDAFs, including Prio3, require fields that are suitable for efficient computation of the number theoretic transform (NTT) [SML24], as this allows for fast polynomial interpolation. Specifically, a field is said to be "NTT-friendly" if, in addition to the interface described in Section 6.1, it provides the following interface:¶
Field.gen() -> Self
is a class method that returns the generator of a large
subgroup of the multiplicative group. To be NTT-friendly, the order of this
subgroup MUST be a power of 2.¶
GEN_ORDER: int
is the order of the multiplicative subgroup generated by
Field.gen()
. This is the smallest positive integer for which
Field.gen()**Field.GEN_ORDER == Field(1)
.¶
The size of the subgroup dictates how large interpolated polynomials can be. It
is RECOMMENDED that a generator is chosen with order at least 2^20
.¶
Table 3 defines finite fields used in the remainder of this document.¶
Parameter | Field64 | Field128 | Field255 |
---|---|---|---|
MODULUS | 2^32 * 4294967295 + 1 | 2^66 * 4611686018427387897 + 1 | 2^255 - 19 |
ENCODED_SIZE | 8 | 16 | 32 |
Generator | 7^4294967295 | 7^4611686018427387897 | n/a |
GEN_ORDER | 2^32 | 2^66 | n/a |
VDAFs in this specification use eXtendable Output Functions (XOFs) for two purposes:¶
Extracting short, pseudorandom strings we call "seeds" from high entropy inputs¶
Expanding seeds into long, pseudorandom outputs¶
Concrete XOFs implement a class Xof
providing the following interface:¶
SEED_SIZE: int
is the size (in bytes) of a seed.¶
Xof(seed: bytes, dst: bytes, binder: bytes)
constructs an instance of the
XOF from the given seed and a domain separation tag and binder string as
defined in Section 6.2.3. The length of the seed will typically be
SEED_SIZE
, but some XOFs may support multiple seed sizes. The seed MUST be
generated securely, i.e., it is either the output of a CSPRNG or a
previous invocation of the XOF.¶
xof.next(length: int)
returns the next chunk of the output of the
initialized XOF as a byte string. The length of the chunk MUST be length
.¶
The following methods are provided for all concrete XOFs. The first is a class method used to derive a fresh seed from an existing one. The second is an instance method used to compute a sequence of field elements. The third is a class method that provides a one-shot interface for expanding a seed into a field vector.¶
def derive_seed(cls, seed: bytes, dst: bytes, binder: bytes) -> bytes: """ Derive a new seed. Pre-conditions: - `len(seed) == cls.SEED_SIZE` """ xof = cls(seed, dst, binder) return xof.next(cls.SEED_SIZE) def next_vec(self, field: type[F], length: int) -> list[F]: """ Output the next `length` field elements. Pre-conditions: - `field` is sub-class of `Field` - `length > 0` """ m = next_power_of_2(field.MODULUS) - 1 vec: list[F] = [] while len(vec) < length: x = from_le_bytes(self.next(field.ENCODED_SIZE)) x &= m if x < field.MODULUS: vec.append(field(x)) return vec def expand_into_vec(cls, field: type[F], seed: bytes, dst: bytes, binder: bytes, length: int) -> list[F]: """ Expand the input `seed` into a vector of `length` field elements. Pre-conditions: - `field` is sub-class of `Field` - `len(seed) == cls.SEED_SIZE` - `length > 0` """ xof = cls(seed, dst, binder) return xof.next_vec(field, length)¶
This section describes XofTurboShake128, an XOF based on the TurboSHAKE128 function specified in [TurboSHAKE]. This XOF is RECOMMENDED for all use cases for DAFs and VDAFs.¶
TODO Update the [TurboSHAKE] reference to point to the RFC instead of the draft.¶
Pre-conditions:¶
The default seed length is 32
. The seed MAY have a different length, but it
MUST not exceed 255. Otherwise initialization will raise an exception.¶
The length of the domain separation string dst
passed to XofTurboShake128
MUST NOT exceed 65535 bytes. Otherwise initialization will raise an
exception.¶
class XofTurboShake128(Xof): """XOF wrapper for TurboSHAKE128.""" # Associated parameters SEED_SIZE = 32 def __init__(self, seed: bytes, dst: bytes, binder: bytes): self.l = 0 self.m = \ to_le_bytes(len(dst), 2) + dst \ to_le_bytes(len(seed), 1) + seed + \ binder def next(self, length: int) -> bytes: self.l += length # Function `TurboSHAKE128(M, D, L)` is as defined in # Section 2.2 of [TurboSHAKE]. # # Implementation note: rather than re-generate the output # stream each time `next()` is invoked, most implementations # of TurboSHAKE128 will expose an "absorb-then-squeeze" API # that allows stateful handling of the stream. stream = TurboSHAKE128(self.m, 1, self.l) return stream[-length:]¶
The XOF in the previous section can be used safely wherever a XOF is needed in this document. However, there are some situations where TurboSHAKE128 creates a performance bottleneck and a more efficient XOF can be used safely instead.¶
This section describes XofFixedKeyAes128, which is used to implement the IDPF of Poplar1 (Section 8.3). It is NOT RECOMMENDED to use this XOF for any other purpose. See Section 9.6 for a more detailed discussion.¶
XofFixedKeyAes128 uses the AES-128 blockcipher [AES] for most of the computation, thereby taking advantage of the hardware implementations of this blockcipher that are widely available. AES-128 is used in a fixed-key mode of operation; the key is derived during initialization using TurboSHAKE128.¶
Pre-conditions:¶
The length of the seed MUST be 16
.¶
The length of the domain separation string dst
passed to XofFixedKeyAes128
MUST NOT exceed 65535 bytes. Otherwise initialization will raise an
exception.¶
class XofFixedKeyAes128(Xof): """ XOF based on a circular collision-resistant hash function from fixed-key AES. """ # Associated parameters SEED_SIZE = 16 def __init__(self, seed: bytes, dst: bytes, binder: bytes): if len(seed) != self.SEED_SIZE: raise ValueError("incorrect seed size") self.length_consumed = 0 # Use TurboSHAKE128 to derive a key from the binder string # and domain separation tag. Note that the AES key does not # need to be kept secret from any party. However, when used # with an IDPF, we require the binder to be a random nonce. # # Implementation note: this step can be cached across XOF # evaluations with many different seeds. dst_length = to_le_bytes(len(dst), 2) self.fixed_key = TurboSHAKE128( dst_length + dst + binder, 2, 16, ) self.seed = seed def next(self, length: int) -> bytes: offset = self.length_consumed % 16 new_length = self.length_consumed + length block_range = range( self.length_consumed // 16, new_length // 16 + 1 ) self.length_consumed = new_length hashed_blocks = [ self.hash_block(xor(self.seed, to_le_bytes(i, 16))) for i in block_range ] return concat(hashed_blocks)[offset:offset+length] def hash_block(self, block: bytes) -> bytes: """ The multi-instance tweakable circular correlation-robust hash function of [GKWWY20] (Section 4.2). The tweak here is the key that stays constant for all XOF evaluations of the same Client, but differs between Clients. Function `AES128(key, block)` is the AES-128 blockcipher. """ lo, hi = block[:8], block[8:] sigma_block = concat([hi, xor(hi, lo)]) return xor(AES128(self.fixed_key, sigma_block), sigma_block)¶
XOFs are used to map a seed to a finite domain, e.g., a fresh seed or a vector of field elements. To ensure domain separation, derivation is bound to some distinguished domain separation tag. The domain separation tag encodes the following values:¶
The document version (i.e.,VERSION
);¶
The "class" of the algorithm using the output (e.g., DAF, VDAF, or IDPF as defined in Section 8.1);¶
A unique identifier for the algorithm (e.g., VDAF.ID
); and¶
Some indication of how the output is used (e.g., for deriving the measurement shares in Prio3 Section 7).¶
The following algorithm is used in the remainder of this document in order to format the domain separation tag:¶
def format_dst(algo_class: int, algo: int, usage: int) -> bytes: """ Format XOF domain separation tag. Pre-conditions: - `algo_class` in the range `[0, 2^8)` - `algo` in the range `[0, 2^32)` - `usage` in the range `[0, 2^16)` """ return concat([ to_be_bytes(VERSION, 1), to_be_bytes(algo_class, 1), to_be_bytes(algo, 4), to_be_bytes(usage, 2), ])¶
It is also sometimes necessary to bind the output to some ephemeral value that multiple parties need to agree on. We call this input the "binder string".¶
This section describes Prio3, a VDAF for general-purpose aggregation. Prio3 is suitable for a wide variety of aggregation functions, including (but not limited to) sum, mean, standard deviation, histograms, and linear regression. It is compatible with any aggregation function that has the following structure:¶
Each measurement is encoded as a vector over some finite field.¶
Measurement validity is determined by an "arithmetic circuit" evaluated over the encoded measurement. An arithmetic circuit is a function comprised of arithmetic operations in the field. (We specify these in full detail in Section 7.3.2.)¶
The aggregate result is obtained by summing up the encoded measurements and computing some function of the sum.¶
Clients protect the privacy of their measurements by secret sharing them and distributing the shares among the Aggregators. To ensure each measurement is valid, the Aggregators run a multi-party computation on their shares, the result of which is the output of the arithmetic circuit. This involves verification of a "Fully Linear Proof (FLP)" (Section 7.1) generated by the Client. FLPs are the core component of Prio3, as they specify the types of measurements and how they are encoded, verified, and aggregated. In fact Prio3 can be thought of as a transformation of an FLP into a VDAF.¶
Prio3 does not have an aggregation parameter. Instead, each output share is derived from each input share by applying a fixed map. See Section 8 for an example of a VDAF that makes meaningful use of the aggregation parameter.¶
The remainder of this section is structured as follows. The interface of FLPs is described in Section 7.1. The generic transformation of an FLP into Prio3 is specified in Section 7.2. Next, a concrete FLP suitable for any validity circuit is specified in Section 7.3. Finally, variants of Prio3 for various types of aggregation tasks are specified in Section 7.4. Test vectors for each variant can be found in Appendix C.¶
Conceptually, an FLP is a two-party protocol executed by a prover and a
verifier. The verifier is restricted to only access the messages it receives
from the prover via linear queries. In actual use in Prio3, however, the
prover's computation is carried out by the Client, and the verifier's
computation is distributed among the Aggregators. The Client generates a
"proof" of its measurement's validity and distributes shares of the proof to
the Aggregators. During preparation, each Aggregator performs some computation
on its measurement share and proof share locally, then broadcasts the result in
its prep share. The validity decision is then made by the
prep_shares_to_prep()
algorithm (Section 5.2).¶
As usual, we describe the interface implemented by a concrete FLP in terms of
an abstract base class, denoted Flp
, that specifies the set of methods and
parameters a concrete FLP must provide.¶
The parameters provided by a concrete FLP are listed in Table 4. A concrete FLP specifies the following algorithms for generating and verifying proofs of validity (encoding is described below in Section 7.1.1):¶
flp.prove(meas: list[F], prove_rand: list[F], joint_rand: list[F]) ->
list[F]
is the proof-generation algorithm run by the prover. Its inputs are
the encoded measurement, the "prover randomness" prove_rand
, and the "joint
randomness" joint_rand
. The prover randomness is used only by the prover,
but the joint randomness is shared by both the prover and verifier.¶
flp.query(meas: list[F], proof: list[F], query_rand: list[F], joint_rand:
list[F], num_shares: int) -> list[F]
is the linear query algorithm run by the
verifier on the encoded measurement and proof. The result of the query (i.e.,
the output of this function) is called the "verifier message". In addition to
the measurement and proof, this algorithm takes as input the query randomness
query_rand
and the joint randomness joint_rand
. The former is used only
by the verifier. num_shares
specifies the number of shares (more on this
below).¶
flp.decide(verifier: list[F]) -> bool
is the deterministic decision
algorithm run by the verifier. It takes as input the verifier message and
outputs a boolean indicating if the measurement from which it was generated
is valid.¶
Our application requires that the FLP is "fully linear" in the sense defined in [BBCGGI19]. As a practical matter, what this property implies is that, when run on a share of the measurement and proof, the query algorithm outputs a share of the verifier message (hereafter the "verifier share"). Furthermore, the privacy property of the FLP system ensures that the verifier message reveals nothing about the measurement other than the fact that it is valid. Therefore, to decide if a measurement is valid, the Aggregators will run the query algorithm locally, exchange verifier shares, combine them to recover the verifier message, and run the decision algorithm.¶
The query algorithm includes a parameter num_shares
that specifies the number
of shares of the measurement and proof that were generated. If these data are
not secret shared, then num_shares == 1
. This parameter is useful for
normalizing constants in arithmetic circuits so that each Aggregator properly
computes a secret share of the circuit's output. See Section 7.3 for
details.¶
An FLP is executed by the prover and verifier as follows:¶
def run_flp( flp: Flp[Measurement, AggResult, F], meas: list[F], num_shares: int) -> bool: """Run the FLP on an encoded measurement.""" joint_rand = flp.field.rand_vec(flp.JOINT_RAND_LEN) prove_rand = flp.field.rand_vec(flp.PROVE_RAND_LEN) query_rand = flp.field.rand_vec(flp.QUERY_RAND_LEN) # Prover generates the proof. proof = flp.prove(meas, prove_rand, joint_rand) # Shard the measurement and the proof. meas_shares = additive_secret_share( meas, num_shares, flp.field, ) proof_shares = additive_secret_share( proof, num_shares, flp.field, ) # Verifier queries the meas shares and proof shares. verifier_shares = [ flp.query( meas_share, proof_share, query_rand, joint_rand, num_shares, ) for meas_share, proof_share in zip(meas_shares, proof_shares) ] # Combine the verifier shares into the verifier. verifier = flp.field.zeros(len(verifier_shares[0])) for verifier_share in verifier_shares: verifier = vec_add(verifier, verifier_share) # Verifier decides if the measurement is valid. return flp.decide(verifier)¶
The proof system is designed so that, if meas
is valid, then run_flp(flp,
meas, num_shares)
always returns True
. On the other hand, if meas
is
invalid, then as long as joint_rand
and query_rand
are generated uniform
randomly, the output is False
with high probability. False positives are
possible: there is a small probability that a verifier accepts an invalid input
as valid. An FLP is said to be "sound" if this probability is sufficiently
small. The soundness of the FLP depends on a variety of parameters, like the
length of the input and the size of the field. See Section 7.3 for
details.¶
Note that soundness of an FLP system is not the same as robustness for the VDAF that uses it. In particular, soundness of the FLP is necessary, but insufficient for robustness of Prio3 (Section 7). See Section 9.7 for details.¶
We remark that [BBCGGI19] defines a larger class of fully linear proof systems than we consider here. In particular, what is called an "FLP" here is called a 1.5-round, public-coin, interactive oracle proof system in their paper.¶
Parameter | Description |
---|---|
PROVE_RAND_LEN: int
|
Length of the prover randomness, the number of random field elements consumed by the prover when generating a proof. |
QUERY_RAND_LEN: int
|
Length of the query randomness, the number of random field elements consumed by the verifier. |
JOINT_RAND_LEN: int
|
Length of the joint randomness, the number of random field elements shared by the prover and verifier. |
MEAS_LEN: int
|
Length of the encoded measurement (Section 7.1.1). |
OUTPUT_LEN: int
|
Length of the aggregatable output (Section 7.1.1). |
PROOF_LEN: int
|
Length of the proof. |
VERIFIER_LEN: int
|
Length of the verifier message generated by querying the measurement and proof. |
Measurement
|
Type of the measurement. |
AggResult
|
Type of the aggregate result. |
field: type[F]
|
Class object for the field (Section 6.1). |
The type of measurement being aggregated is defined by the FLP. Hence, the FLP also specifies a method of encoding raw measurements as a vector of field elements:¶
flp.encode(measurement: Measurement) -> list[F]
encodes a raw measurement
as a vector of field elements.¶
Post-conditions:¶
The encoded measurement MUST have length flp.MEAS_LEN
.¶
For some FLPs, the encoded measurement also includes redundant field elements
that are useful for checking the proof, but which are not needed after the
proof has been checked. An example is the Sum
type defined in Section 7.4.2
for which each measurement is an integer in the range [0, max_measurement]
.
The range check requires encoding the measurement with several field elements,
though just one is needed for aggregation. Thus the FLP defines an algorithm
for truncating the encoded measurement to the length of the aggregatable output:¶
flp.truncate(meas: list[F]) -> list[F]
maps an encoded measurement (e.g.,
the bit-encoding of the measurement) to an aggregatable output (e.g., the
singleton vector containing the measurement).¶
Pre-conditions:¶
The length of the input MUST be flp.MEAS_LEN
¶
Post-conditions:¶
The length of the output MUST be flp.OUTPUT_LEN
.¶
Once the aggregate shares have been transmitted to the Collector, their sum can be converted into the aggregate result. This could be a projection from the FLP's field to the integers, or it could include additional post-processing. Either way, this functionality is implemented by the following method:¶
flp.decode(output: list[F], num_measurements: int) -> AggResult
maps a sum
of aggregate shares to an aggregate result.¶
Pre-conditions:¶
We remark that, taken together, these three functionalities correspond to the notion of "Affine-aggregatable encodings (AFEs)" from [CGB17].¶
It is sometimes desirable to generate and verify multiple independent proofs for the same input. First, this improves the soundness of the proof system without having to change any of its parameters. Second, it allows a smaller field to be used (e.g., replace Field128 with Field64) without sacrificing soundness. This is useful because it reduces the overall communication of the protocol. (This is a trade-off, of course, since generating and verifying more proofs requires more time.) Given these benefits, this feature is implemented by Prio3 (Section 7).¶
To generate these proofs for a specific measurement, the prover calls
flp.prove()
multiple times, each time using fresh prover and joint
randomness. The verifier checks each proof independently, each time with fresh
query randomness. It accepts the measurement only if the decision algorithm
accepts on each proof.¶
See Section 9.7 for guidance on choosing the field size and number of proofs.¶
This section specifies Prio3
, an implementation of the Vdaf
interface
defined in Section 5. The parameters and types required by the Vdaf
interface
are defined in Table 5. The methods required for sharding, preparation,
aggregation, and unsharding are described in the remaining subsections. These
methods refer to constants enumerated in Table 6.¶
Parameter | Value |
---|---|
flp
|
An instance of Flp (Section 7.1). |
xof
|
XofTurboShake128 (Section 6.2.1) |
PROOFS
|
Any int in the range [1, 256) . |
VERIFY_KEY_SIZE
|
xof.SEED_SIZE
|
RAND_SIZE
|
xof.SEED_SIZE * SHARES if flp.JOINT_RAND_LEN == 0 else 2 * xof.SEED_SIZE * SHARES
|
NONCE_SIZE
|
16
|
ROUNDS
|
1
|
SHARES
|
Any int in the range [2, 256) . |
Measurement
|
As defined by flp . |
AggParam
|
None
|
PublicShare
|
Optional[list[bytes]]
|
InputShare
|
tuple[list[F], list[F], Optional[bytes]] | tuple[bytes, Optional[bytes]]
|
OutShare
|
list[F]
|
AggShare
|
list[F]
|
AggResult
|
As defined by flp . |
PrepState
|
tuple[list[F], Optional[bytes]]
|
PrepShare
|
tuple[list[F], Optional[bytes]]
|
PrepMessage
|
Optional[bytes]
|
Variable | Value |
---|---|
USAGE_MEAS_SHARE: int
|
1 |
USAGE_PROOF_SHARE: int
|
2 |
USAGE_JOINT_RANDOMNESS: int
|
3 |
USAGE_PROVE_RANDOMNESS: int
|
4 |
USAGE_QUERY_RANDOMNESS: int
|
5 |
USAGE_JOINT_RAND_SEED: int
|
6 |
USAGE_JOINT_RAND_PART: int
|
7 |
This section describes the process of recovering output shares from the input shares. The high-level idea is that each Aggregator first queries its measurement share and proof(s) share(s) locally, then broadcasts its verifier share(s) in its prep share. The shares of verifier(s) are then combined into the verifier message(s) used to decide whether to accept.¶
In addition, the Aggregators must recompute the same joint randomness used by the Client to generate the proof(s). In order to avoid an extra round of communication, the Client includes the joint randomness parts in the public share. This leaves open the possibility that the Client cheated by, say, forcing the Aggregators to use joint randomness that biases the proof check procedure some way in its favor. To mitigate this, the Aggregators also check that they have all computed the same joint randomness seed before accepting their output shares. To do so, they exchange their parts of the joint randomness along with their shares of verifier(s).¶
Implementation note: the prep state for Prio3 includes the output share that will be released once preparation is complete. In some situations, it may be necessary for the Aggregator to encode this state as bytes and store it for retrieval later on. For all but the first Aggregator, it is possible to save storage by storing the measurement share rather than output share itself. It is relatively inexpensive to expand this seed into the measurement share, then truncate the measurement share to get the output share.¶
All functions used in the following listing are defined in Section 7.2.6:¶
def prep_init( self, verify_key: bytes, ctx: bytes, agg_id: int, _agg_param: None, nonce: bytes, public_share: Optional[list[bytes]], input_share: Prio3InputShare[F]) -> tuple[ Prio3PrepState[F], Prio3PrepShare[F]]: joint_rand_parts = public_share (meas_share, proofs_share, blind) = \ self.expand_input_share(ctx, agg_id, input_share) out_share = self.flp.truncate(meas_share) # Compute the joint randomness. joint_rand: list[F] = [] corrected_joint_rand_seed, joint_rand_part = None, None if self.flp.JOINT_RAND_LEN > 0: assert blind is not None assert joint_rand_parts is not None joint_rand_part = self.joint_rand_part( ctx, agg_id, blind, meas_share, nonce) joint_rand_parts[agg_id] = joint_rand_part corrected_joint_rand_seed = self.joint_rand_seed( ctx, joint_rand_parts) joint_rands = self.joint_rands( ctx, corrected_joint_rand_seed) # Query the measurement and proof(s) share(s). query_rands = self.query_rands(verify_key, ctx, nonce) verifiers_share = [] for _ in range(self.PROOFS): proof_share, proofs_share = front( self.flp.PROOF_LEN, proofs_share) query_rand, query_rands = front( self.flp.QUERY_RAND_LEN, query_rands) if self.flp.JOINT_RAND_LEN > 0: joint_rand, joint_rands = front( self.flp.JOINT_RAND_LEN, joint_rands) verifiers_share += self.flp.query( meas_share, proof_share, query_rand, joint_rand, self.SHARES, ) prep_state = (out_share, corrected_joint_rand_seed) prep_share = (verifiers_share, joint_rand_part) return (prep_state, prep_share) def prep_shares_to_prep( self, ctx: bytes, _agg_param: None, prep_shares: list[Prio3PrepShare[F]]) -> Optional[bytes]: # Unshard each set of verifier shares into each verifier message. verifiers = self.flp.field.zeros( self.flp.VERIFIER_LEN * self.PROOFS) joint_rand_parts = [] for (verifiers_share, joint_rand_part) in prep_shares: verifiers = vec_add(verifiers, verifiers_share) if self.flp.JOINT_RAND_LEN > 0: assert joint_rand_part is not None joint_rand_parts.append(joint_rand_part) # Verify that each proof is well-formed and input is valid. for _ in range(self.PROOFS): verifier, verifiers = front(self.flp.VERIFIER_LEN, verifiers) if not self.flp.decide(verifier): raise ValueError('proof verifier check failed') # Combine the joint randomness parts computed by the # Aggregators into the true joint randomness seed. This is # used in the last step. joint_rand_seed = None if self.flp.JOINT_RAND_LEN > 0: joint_rand_seed = self.joint_rand_seed(ctx, joint_rand_parts) return joint_rand_seed def prep_next( self, _ctx: bytes, prep_state: Prio3PrepState[F], prep_msg: Optional[bytes] ) -> tuple[Prio3PrepState[F], Prio3PrepShare[F]] | list[F]: joint_rand_seed = prep_msg (out_share, corrected_joint_rand_seed) = prep_state # If joint randomness was used, check that the value computed by # the Aggregators matches the value indicated by the Client. if joint_rand_seed != corrected_joint_rand_seed: raise ValueError('joint randomness check failed') return out_share¶
Prio3
only permits a report to be aggregated once.¶
def is_valid( self, _agg_param: None, previous_agg_params: list[None]) -> bool: return len(previous_agg_params) == 0¶
Aggregating a set of output shares is simply a matter of adding up the vectors element-wise.¶
def agg_init(self, _agg_param: None) -> list[F]: return self.flp.field.zeros(self.flp.OUTPUT_LEN) def agg_update(self, _agg_param: None, agg_share: list[F], out_share: list[F]) -> list[F]: return vec_add(agg_share, out_share) def merge(self, _agg_param: None, agg_shares: list[list[F]]) -> list[F]: agg = self.agg_init(None) for agg_share in agg_shares: agg = vec_add(agg, agg_share) return agg¶
To unshard a set of aggregate shares, the Collector first adds up the vectors element-wise, then decodes the aggregate result from the sum according to the FLP (Section 7.1.1).¶
def unshard( self, _agg_param: None, agg_shares: list[list[F]], num_measurements: int) -> AggResult: agg = self.merge(None, agg_shares) return self.flp.decode(agg, num_measurements)¶
This section defines a number of auxiliary functions referenced by the main algorithms for Prio3 in the preceding sections.¶
def helper_meas_share( self, ctx: bytes, agg_id: int, share: bytes) -> list[F]: return self.xof.expand_into_vec( self.flp.field, share, self.domain_separation_tag(USAGE_MEAS_SHARE, ctx), byte(agg_id), self.flp.MEAS_LEN, ) def helper_proofs_share( self, ctx: bytes, agg_id: int, share: bytes) -> list[F]: return self.xof.expand_into_vec( self.flp.field, share, self.domain_separation_tag(USAGE_PROOF_SHARE, ctx), byte(self.PROOFS) + byte(agg_id), self.flp.PROOF_LEN * self.PROOFS, ) def expand_input_share( self, ctx: bytes, agg_id: int, input_share: Prio3InputShare[F]) -> tuple[ list[F], list[F], Optional[bytes]]: if agg_id > 0: assert len(input_share) == 2 (share, blind) = input_share meas_share = self.helper_meas_share(ctx, agg_id, share) proofs_share = self.helper_proofs_share(ctx, agg_id, share) else: assert len(input_share) == 3 (meas_share, proofs_share, blind) = input_share return (meas_share, proofs_share, blind) def prove_rands(self, ctx: bytes, prove_seed: bytes) -> list[F]: return self.xof.expand_into_vec( self.flp.field, prove_seed, self.domain_separation_tag(USAGE_PROVE_RANDOMNESS, ctx), byte(self.PROOFS), self.flp.PROVE_RAND_LEN * self.PROOFS, ) def query_rands( self, verify_key: bytes, ctx: bytes, nonce: bytes) -> list[F]: return self.xof.expand_into_vec( self.flp.field, verify_key, self.domain_separation_tag(USAGE_QUERY_RANDOMNESS, ctx), byte(self.PROOFS) + nonce, self.flp.QUERY_RAND_LEN * self.PROOFS, ) def joint_rand_part( self, ctx: bytes, agg_id: int, blind: bytes, meas_share: list[F], nonce: bytes) -> bytes: return self.xof.derive_seed( blind, self.domain_separation_tag(USAGE_JOINT_RAND_PART, ctx), byte(agg_id) + nonce + self.flp.field.encode_vec(meas_share), ) def joint_rand_seed(self, ctx: bytes, joint_rand_parts: list[bytes]) -> bytes: """Derive the joint randomness seed from its parts.""" return self.xof.derive_seed( zeros(self.xof.SEED_SIZE), self.domain_separation_tag(USAGE_JOINT_RAND_SEED, ctx), concat(joint_rand_parts), ) def joint_rands(self, ctx: bytes, joint_rand_seed: bytes) -> list[F]: """Derive the joint randomness from its seed.""" return self.xof.expand_into_vec( self.flp.field, joint_rand_seed, self.domain_separation_tag(USAGE_JOINT_RANDOMNESS, ctx), byte(self.PROOFS), self.flp.JOINT_RAND_LEN * self.PROOFS, )¶
This section defines serialization formats for messages exchanged over the network while executing Prio3. Messages are defined in the presentation language of TLS as defined in Section 3 of [RFC8446].¶
Let prio3
denote an instance of Prio3
. In the remainder we use S
as an
alias for prio3.xof.SEED_SIZE
and F
as an alias for
prio3.field.ENCODED_SIZE
. XOF seeds are represented as follows:¶
opaque Prio3Seed[S];¶
Field elements are encoded in little-endian byte order (as defined in Section 6.1) and represented as follows:¶
opaque Prio3Field[F];¶
When joint randomness is not used, the prep message is the empty string. Otherwise the prep message consists of the joint randomness seed computed by the Aggregators:¶
struct { Prio3Seed joint_rand; } Prio3PrepMessageWithJointRand;¶
Aggregate shares are structured as follows:¶
struct { Prio3Field agg_share[F * prio3.flp.OUTPUT_LEN]; } Prio3AggShare;¶
This section specifies an implementation of the Flp
interface (Section 7.1) based
on the construction from [BBCGGI19], Section 4.2. The types and parameters
required by this interface are listed in the table below.¶
We begin in Section 7.3.1 with an overview of the proof system and some extensions to it. Section 7.3.2 defines validity circuits, the core component of the proof system that determines measurement validity and how measurements are aggregated. The proof-generation algorithm, query algorithm, and decision algorithm are defined in Section 7.3.3, Section 7.3.4, and Section 7.3.5 respectively.¶
Parameter | Value |
---|---|
valid
|
An instance of Valid (Section 7.3.2). |
field
|
valid.field
|
PROVE_RAND_LEN
|
valid.prove_rand_len()
|
QUERY_RAND_LEN
|
valid.query_rand_len()
|
JOINT_RAND_LEN
|
valid.JOINT_RAND_LEN
|
MEAS_LEN
|
valid.MEAS_LEN
|
OUTPUT_LEN
|
valid.OUTPUT_LEN
|
PROOF_LEN
|
valid.proof_len()
|
VERIFIER_LEN
|
valid.verifier_len()
|
Measurement
|
As defined by valid . |
AggResult
|
As defined by valid . |
An FLP is a type of "zero-knowledge proof". A conventional zero-knowledge proof system involves two parties:¶
The prover, who holds a measurement and generates a proof of the measurement's validity¶
The verifier who holds an encryption of, or commitment to, the measurement and checks the proof¶
Our proof system is much the same, except the verifier is split across multiple Aggregators, each of which has a secret share of the measurement rather than a commitment to it.¶
Validity is defined in terms of an arithmetic circuit evaluated over the measurement. The inputs to this circuit are elements of a finite field that comprise the encoded measurement; the gates of the circuit are multiplication, addition, and subtraction operations; and the output of the circuit is a single field element. If the value is zero, then the measurement is deemed valid; otherwise, if the output is non-zero, then the measurement is deemed invalid.¶
For example, the simplest circuit specified in this document is the following (Section 7.4.1):¶
C(x) = x * (x-1)¶
This circuit contains one subtraction gate (x-1
) and one multiplication gate
(x * (x-1)
). Observe that C(x) = 0
if and only if x
is in the range
[0, 2)
.¶
The goal of the proof system is to allow each Aggregator to privately and
correctly compute a share of C(x)
from its share of x
. Then all they need
to do to determine validity is to broadcast their shares of C(x)
.¶
Suppose for a moment that C
is an affine arithmetic circuit, meaning its only
operations are addition, subtraction, and multiplication-by-constant. (The
circuit above is non-affine because it contains a multiplication gate with two
non-constant inputs.) Then each Aggregator can compute its share locally, since¶
C(x_shares[0] + ... + x_shares[SHARES-1]) = C(x_shares[0]) + ... + C(x_shares[SHARES-1])¶
(Note that, for this equality to hold, it is necessary to scale any addition of
a constant in the circuit by 1/SHARES
.) However, this is not the case if C
contains multiplication gates with two non-constant inputs. Thus our goal is to
transform these multiplication gates into computations on secret shared data
that each Aggregator can perform locally.¶
The key idea is to have the prover construct a polynomial p
such that p(j)
is equal to the output of the j
-th multiplication gate. Polynomial evaluation
is fully linear, which means the coefficients of the polynomial can be secret
shared in a way that allows each Aggregator to compute a share of p(j)
for
any j
. These intermediate results can then be combined with the affine
arithmetic operations of the validity circuit to produce the final output.¶
Applying this idea to the example circuit C
above:¶
The Client, given its measurement x
, constructs the lowest degree
polynomial p
for which p(0) = s
and p(1) = x * (x-1)
, where s
is a
random blinding value generated by the Client. (The blinding value is to
protect the privacy of the measurement.) It then sends shares of x
and
shares of the coefficients of p
to each of the Aggregators.¶
Each Aggregator locally computes and broadcasts its share of p(1)
, which
is equal to its share of C(x)
.¶
In fact, our FLP is slightly more general than this. We can replace the multiplication gate with any non-affine sub-circuit and apply the same idea. For example, in Section 7.4.2, the validity circuit uses the following sub-circuit multiple times:¶
Range2(x) = x * (x-1) = x^2 - x¶
(This is the same functionality computed by the example circuit C
above.)
Here again we can interpolate the lowest degree polynomial p
for which p(j)
is the value of the j
-th call to Range2
in the validity circuit. Each
validity circuit defines a sub-circuit that encapsulates its non-affine
arithmetic operations. We refer to this sub-circuit as the "gadget".¶
Finally, the proof system has one more important component. It is possible for
a malicious Client to produce a gadget polynomial p
that would result in
C(x)
being computed incorrectly, potentially resulting in an invalid
measurement being accepted. To prevent this, the Aggregators perform a
probabilistic test to check that the gadget polynomial was constructed
properly. This "gadget test", and the procedure for constructing the
polynomial, are described in detail in Section 7.3.3.¶
The FLP described in Section 7.3 extends the proof system of [BBCGGI19], Section 4.2 in a few ways.¶
First, the validity circuit in our construction includes an additional, random
input (this is the "joint randomness" derived from the measurement shares in
Prio3; see Section 7.2). This allows for circuit optimizations that
trade a small soundness error for a shorter proof. For example, consider a
circuit that recognizes the set of length-N
vectors for which each element is
either one or zero. A deterministic circuit could be constructed for this
language, but it would involve a large number of multiplications that would
result in a large proof. (See the discussion in [BBCGGI19], Section 5.2 for
details). A much shorter proof can be constructed for the following randomized
circuit:¶
C(x, r) = r * Range2(x[0]) + ... + r^N * Range2(x[N-1])¶
(Note that this is a special case of [BBCGGI19], Theorem 5.2.) Here x
is
the length-N
input and r
is a random field element. The gadget circuit
Range2
is the "range-check" polynomial described above, i.e., Range2(x) =
x^2 - x
. The idea is that, if x
is valid, i.e., each x[j]
is in
the range [0, 2)
, then the circuit will evaluate to zero regardless of the
value of r
; but if some x[j]
is not in the range [0, 2)
, then the output
will be non-zero with high probability.¶
The second extension implemented by our FLP allows the validity circuit to contain multiple gadget types. (This generalization was suggested in [BBCGGI19], Remark 4.5.) This provides additional flexibility for designing circuits by allowing multiple, non-affine sub-circuits. For example, the following circuit is allowed:¶
C(x, r) = r * Range2(x[0]) + ... + r^L * Range2(x[L-1]) + \ r^(L+1) * Range3(x[L]) + ... + r^N * Range3(x[N-1])¶
where Range3(x) = x^3 - 3x^2 + 2x
. This circuit checks that the first L
inputs are in the range [0, 2)
and the last N-L
inputs are in the range
[0, 3)
. The same circuit can be expressed using a simpler gadget, namely
multiplication, but the resulting proof would be longer.¶
Third, rather than interpolate the gadget polynomial at inputs 1
, 2
, ...,
j
, ..., where j
is the j
-th invocation of the gadget, we use roots of
unity for the field. This allows us to construct each gadget polynomial via the
number theoretic transform [SML24], which is far more efficient than generic
formulas. Note that the roots of unity are powers of the generator for the
NTT-friendly field (see Section 6.1.2).¶
Finally, the validity circuit in our FLP may have any number of outputs (at least one). The input is said to be valid if each of the outputs is zero. To save bandwidth, we take a random linear combination of the outputs. If each of the outputs is zero, then the reduced output will be zero; but if one of the outputs is non-zero, then the reduced output will be non-zero with high probability.¶
An instance of the proof system is defined in terms of a validity circuit that
implements the Valid
interface specified in this section. The parameters are
listed in the table below.¶
Parameter | Description |
---|---|
GADGETS: list[Gadget]
|
A list of gadgets. |
GADGET_CALLS: list[int]
|
Number of times each gadget is called. |
MEAS_LEN: int
|
Length of the measurement. |
JOINT_RAND_LEN: int
|
Length of the joint randomness. |
EVAL_OUTPUT_LEN: int
|
Length of the circuit output. |
OUTPUT_LEN: int
|
Length of the aggregatable output. |
Measurement
|
Type of the measurement. |
AggResult
|
Type of the aggregate result. |
field: type[F]
|
Class object for the field (Section 6.1.2) |
The circuit is invoked with the following method:¶
valid.eval(meas: list[F], joint_rand: list[F], num_shares: int) -> list[F]
evaluates the arithmetic circuit on a measurement and joint randomness. The
output is a list of field elements: if every element is equal to
valid.field(0)
, then the circuit is said to "accept" the measurement;
otherwise, if any element is not equal to valid.field(0)
, then the circuit
is said to "reject" the measurement.¶
This method can also be called on a secret share of the measurement, in which case it produces a secret share of the output.¶
The circuit must be composed of affine gates and gadget calls, so that the
verifier may check the prover's proof and circuit evaluation using linear
queries. This means that all non-affine multiplications in the circuit must
be encapsulated in gadget calls. Additions of constants must be rescaled by
the inverse of num_shares
.¶
Pre-conditions:¶
The length of meas
MUST be valid.MEAS_LEN
.¶
The length of joint_rand
MUST be valid.JOINT_RAND_LEN
.¶
num_shares
MUST be the number of secret shares of meas
, or 1
if
meas
is not secret shared.¶
Post-conditions:¶
The length of the output MUST be valid.EVAL_OUTPUT_LEN
.¶
Each circuit has a list of gadgets, denoted GADGETS
, that are invoked by
valid.eval()
. The circuit evaluated by the gadget should be non-affine, and MUST
be arithmetic, i.e., composed only of multiplication, addition, and subtraction
gates. An instance of class Gadget
has the following interface:¶
ARITY: int
is the number of input wires. For example, the multiplication
gadget Mul(x,y) = x*y
has arity of 2.¶
DEGREE: int
is the arithmetic degree of the gadget circuit. This is defined
to be the degree of the polynomial that computes it. This exists
because the circuit is arithmetic. For example, Mul
has degree 2.¶
gadget.eval(field: type[F], inp: list[F]) -> F
evaluates the gadget over
the given inputs and field.¶
gadget.eval_poly(field: type[F], inp_poly: list[list[F]]) -> list[F]
is the
same as gadget.eval()
except it evaluates the circuit over the polynomial
ring of the field. This is well defined because the circuit is arithmetic.¶
In addition to the list of gadgets, the validity circuit specifies how many
times each gadget is called (GADGET_CALLS
). The circuit needs to define an
ordering of the calls it makes to each gadget, so that all parties agree on how
to identify recorded wire values. It also specifies the length of the circuit's
input (MEAS_LEN
), the length of the joint randomness (JOINT_RAND_LEN
), and
the length of the circuit's output (EVAL_OUTPUT_LEN
).¶
A validity circuit also specifies parameters and methods needed for Prio3 aggregation. These are used to implement the interface in Section 7.1.1:¶
valid.encode(measurement: Measurement) -> list[F]
returns a vector of
length MEAS_LEN
representing a measurement of type Measurement
.¶
valid.truncate(meas: list[F]) -> list[F]
returns a vector of length
OUTPUT_LEN
representing (a share of) an aggregatable output.¶
valid.decode(agg: list[F], num_measurements: int) -> AggResult
returns an
aggregate result of type AggResult
. This computation may depend on the
number of outputs aggregated.¶
Finally, the following are helper methods used to instantiate parameters of the
Flp
interface (Section 7.1):¶
def prove_rand_len(self) -> int: """Length of the prover randomness.""" return sum(g.ARITY for g in self.GADGETS) def query_rand_len(self) -> int: """Length of the query randomness.""" query_rand_len = len(self.GADGETS) if self.EVAL_OUTPUT_LEN > 1: query_rand_len += self.EVAL_OUTPUT_LEN return query_rand_len def proof_len(self) -> int: """Length of the proof.""" length = 0 for (g, g_calls) in zip(self.GADGETS, self.GADGET_CALLS): p = next_power_of_2(1 + g_calls) length += g.ARITY + g.DEGREE * (p - 1) + 1 return length def verifier_len(self) -> int: """Length of the verifier message.""" length = 1 for g in self.GADGETS: length += g.ARITY + 1 return length¶
The proof generation algorithm invokes the validity circuit on the encoded measurement and joint randomness. The validity circuit in turn invokes the gadgets defined by the circuit. The prove randomness is used to construct the gadget polynomials that the verifier will use to compute the outputs of each gadget.¶
To generate the gadget polynomials, the prover evaluates the validity circuit,
and records the values on each input wire of each call to each gadget. This is
accomplished by "wrapping" each gadget in a class ProveGadget
that records
the wire inputs. We list this class in Appendix A.4. We denote the value
of the j
-th wire for the k
-th invocation of gadget g
as g.wires[j][k]
.¶
Next, we compute each of the "wire polynomials" for each gadget. The j
-th
wire polynomial is the lowest degree polynomial that evaluates to
g.wire[j][k]
at a sequence of fixed points. We obtain the gadget polynomial by
evaluating the gadget on the wire polynomials.¶
def prove(self, meas: list[F], prove_rand: list[F], joint_rand: list[F]) -> list[F]: # Evaluate the validity circuit, recording the value of each # input wire for each evaluation of each gadget. valid = ProveGadget.wrap(self.valid, prove_rand) valid.eval(meas, joint_rand, 1) # Construct the proof, which consists of the wire seeds and # gadget polynomial for each gadget. proof = [] for g in cast(list[ProveGadget[F]], valid.GADGETS): p = len(g.wires[0]) # Compute the wire polynomials for this gadget. For each `j`, # find the lowest degree polynomial `wire_poly` for which # `wire_poly(alpha^k) = g.wires[j][k]` for all `k`. Note that # each `g.wires[j][0]` is set to the seed of wire `j`, which # is included in the prove randomness. # # Implementation note: `alpha` is a root of unity, which # means `poly_interp()` can be evaluated using the NTT. Note # that `g.wires[j]` is padded with 0s to a power of 2. alpha = self.field.gen() ** (self.field.GEN_ORDER // p) wire_inp = [alpha ** k for k in range(p)] wire_polys = [] for j in range(g.ARITY): wire_poly = poly_interp(self.field, wire_inp, g.wires[j]) wire_polys.append(wire_poly) # Compute the gadget polynomial by evaluating the gadget on # the wire polynomials. By construction we have that # `gadget_poly(alpha^k)` is the `k`-th output. gadget_poly = g.eval_poly(self.field, wire_polys) for j in range(g.ARITY): proof.append(g.wires[j][0]) proof += gadget_poly return proof¶
The query algorithm invokes the validity circuit on the encoded measurement and joint randomness. It evaluates the gadget polynomials encoded by the proof (share) to produce (a share of) each gadget output. The verifier (share) consists of (a share of) the validity circuit's output and (a share of) each gadget test. The gadget tests consume the query randomness.¶
The goal of each gadget test is to ensure the inputs used by the prover to generate the gadget polynomial match the inputs we used to evaluate it. We do this by partially reconstructing the gadget polynomial and evaluating it at a random point: when we evaluate the gadget polynomial at the same point, we expect to get the same result.¶
To start a gadget test, we first construct the (shares of the) wire polynomials
just as the prover did. First, we record the input (share) of the j
-th wire
of the k
-th invocation of the gadget as g.wires[j][k]
. Again, this is
accomplished by a wrapper gadget, QueryGadget
, listed in Appendix A.4.
This gadget also evaluates the gadget polynomial for each gadget invocation in
order to produce the gadget's output. Then we compute the wire polynomials from
the recorded values.¶
Next, we choose a random point t
(parsed from the query randomness), evaluate
each wire polynomial at t
, and evaluate the gadget polynomial at t
. The
results are recorded in the verifier message passed to the decision algorithm,
where we finish the test.¶
The random point t
MUST NOT be one of the fixed evaluation points used to
interpolate the wire polynomials. Otherwise, the verifier message may partially
leak the encoded measurement.¶
def query(self, meas: list[F], proof: list[F], query_rand: list[F], joint_rand: list[F], num_shares: int) -> list[F]: # Evaluate the validity circuit, recording the value of each # input wire for each evaluation of each gadget. Use the gadget # polynomials encoded by `proof` to compute the gadget outputs. valid = QueryGadget.wrap(self.valid, proof) out = valid.eval(meas, joint_rand, num_shares) # Reduce the output. if self.valid.EVAL_OUTPUT_LEN > 1: (rand, query_rand) = front( self.valid.EVAL_OUTPUT_LEN, query_rand, ) v = self.field(0) for (r, out_elem) in zip(rand, out): v += r * out_elem else: [v] = out # Construct the verifier message, which consists of the reduced # circuit output and each gadget test. verifier = [v] for (g, t) in zip(cast(list[QueryGadget[F]], valid.GADGETS), query_rand): p = len(g.wires[0]) # Abort if `t` is one of the inputs used to compute the wire # polynomials so that the verifier message doesn't leak the # gadget output. It suffices to check if `t` is a root of # unity, which implies it is a power of `alpha`. if t ** p == self.field(1): raise ValueError('test point is a root of unity') # To test the gadget, we re-compute the wire polynomials and # check for consistency with the gadget polynomial provided # by the prover. To start, evaluate the gadget polynomial and # each of the wire polynomials at the random point `t`. wire_checks = [] wire_inp = [g.alpha ** k for k in range(p)] for j in range(g.ARITY): wire_poly = poly_interp(self.field, wire_inp, g.wires[j]) wire_checks.append(poly_eval(self.field, wire_poly, t)) gadget_check = poly_eval(self.field, g.poly, t) verifier += wire_checks verifier.append(gadget_check) return verifier¶
The decision algorithm consumes the verifier message. (Each of the Aggregators computes an additive share of the verifier message after the previous step.) The verifier message consists of the reduced circuit output and the gadget tests.¶
To finish each gadget test, we evaluate the gadget on the wire checks: if the encoded measurement and joint randomness used to generate the proof are the same as the measurement (share) and joint randomness used to verify the proof, then the output of the gadget will be equal to the gadget check; otherwise, the output will not equal the gadget check with high probability.¶
def decide(self, verifier: list[F]) -> bool: # Check the output of the validity circuit. ([v], verifier) = front(1, verifier) if v != self.field(0): return False # Complete each gadget test. for g in self.valid.GADGETS: (wire_checks, verifier) = front(g.ARITY, verifier) ([gadget_check], verifier) = front(1, verifier) if g.eval(self.field, wire_checks) != gadget_check: return False return True¶
This section specifies instantiations of Prio3 for various aggregation tasks. Each variant is determined by a field (Section 6.1), a validity circuit (Section 7.3.2),and the number of proofs to generate and verify. All gadgets are listed in Appendix A. Test vectors for each can be found in Appendix C.¶
Parameter | Value |
---|---|
field
|
Field64 (Table 3) |
Valid
|
Count(field) (this section) |
PROOFS
|
1
|
Our first variant of Prio3 is for a simple counter: each measurement is either
one or zero and the aggregate result is the sum of the measurements. Its
validity circuit uses the multiplication gadget Mul
specified in
Appendix A.1, which takes two inputs and multiplies them. The circuit is
specified below:¶
class Count(Valid[int, int, F]): GADGETS: list[Gadget[F]] = [Mul()] GADGET_CALLS = [1] MEAS_LEN = 1 JOINT_RAND_LEN = 0 OUTPUT_LEN = 1 EVAL_OUTPUT_LEN = 1 # Class object for the field. field: type[F] def __init__(self, field: type[F]): self.field = field def encode(self, measurement: int) -> list[F]: return [self.field(measurement)] def eval( self, meas: list[F], joint_rand: list[F], _num_shares: int) -> list[F]: squared = self.GADGETS[0].eval(self.field, [meas[0], meas[0]]) return [squared - meas[0]] def truncate(self, meas: list[F]) -> list[F]: return meas def decode(self, output: list[F], _num_measurements: int) -> int: return output[0].int()¶
Parameter | Value |
---|---|
field
|
Field64 (Table 3) |
Valid
|
Sum(field, max_measurement) (this section) |
PROOFS
|
1
|
The next variant of Prio3 supports summing of integers in a pre-determined
range. Each measurement is an integer in the range [0, max_measurement]
,
where max_measurement
defines the largest valid measurement.¶
The range check is accomplished by encoding the measurement as a bit vector, encoding the measurement plus an offset as a bit vector, then checking that the two encoded integers are consistent. Let¶
bits = max_measurement.bit_length()
, the number of bits needed to encode
the largest valid measurement¶
offset = 2^bits - 1 - max_measurement
¶
The first bit-encoded integer is the measurement itself. Note that only
measurements between 0
and 2^bits - 1
can be encoded this way with as many
bits. The second bit-encoded integer is the sum of the measurement and
offset
. Observe that this sum can only be encoded this way if it is between
0
and 2^bits - 1
, which implies that the measurement is between -offset
and max_measurement
.¶
The circuit first checks that each entry of both bit vectors is a one or a
zero. It then decodes both the measurement and the offset measurement, and
subtracts the offset from the latter. It then checks if these two values are
equal. Since both the measurement and the measurement plus offset
are in the
same range of [0, 2^bits)
, this means that the measurement itself is between
0
and max_measurement
.¶
The circuit uses the polynomial-evaluation gadget PolyEval
specified in
Appendix A.2. The polynomial is p(x) = x^2 - x
, which is equal to 0
if and only if x
is in the range [0, 2)
. The complete circuit is specified
below:¶
Note that decoding a sequence of bits into an integer is a linear operation, specifically, a linear combination with a sequence of powers of two, so it can be done within a validity circuit using "free" affine gates. Furthermore, decoding secret shares of a bit-encoded integer will produce secret shares of the original integer.¶
class Sum(Valid[int, int, F]): GADGETS: list[Gadget[F]] = [PolyEval([0, -1, 1])] JOINT_RAND_LEN = 0 OUTPUT_LEN = 1 field: type[F] def __init__(self, field: type[F], max_measurement: int): self.field = field self.bits = max_measurement.bit_length() self.offset = self.field(2**self.bits - 1 - max_measurement) self.max_measurement = max_measurement self.GADGET_CALLS = [2 * self.bits] self.MEAS_LEN = 2 * self.bits self.EVAL_OUTPUT_LEN = 2 * self.bits + 1 def encode(self, measurement: int) -> list[F]: encoded = [] encoded += self.field.encode_into_bit_vec( measurement, self.bits ) encoded += self.field.encode_into_bit_vec( measurement + self.offset.int(), self.bits ) return encoded def eval( self, meas: list[F], joint_rand: list[F], num_shares: int) -> list[F]: shares_inv = self.field(num_shares).inv() out = [] for b in meas: out.append(self.GADGETS[0].eval(self.field, [b])) range_check = self.offset * shares_inv + \ self.field.decode_from_bit_vec(meas[:self.bits]) - \ self.field.decode_from_bit_vec(meas[self.bits:]) out.append(range_check) return out def truncate(self, meas: list[F]) -> list[F]: return [self.field.decode_from_bit_vec(meas[:self.bits])] def decode(self, output: list[F], _num_measurements: int) -> int: return output[0].int()¶
Parameter | Value |
---|---|
field
|
Field128 (Table 3) |
Valid
|
SumVec(field, length, bits, chunk_length) (this section) |
PROOFS
|
1
|
This instance of Prio3 supports summing vectors of integers. It has three
parameters: length
, bits
, and chunk_length
. Each measurement is a vector
of positive integers with length equal to the length
parameter. Each element
of the measurement is an integer in the range [0, 2^bits)
. It is RECOMMENDED
to set chunk_length
to an integer near the square root of length * bits
(see Section 7.4.3.1).¶
The circuit is denoted SumVec
. Each measurement is encoded as a vector of
field elements with a length of length * bits
. The field elements in the
encoded vector represent all the bits of the measurement vector's elements,
consecutively, in LSB to MSB order.¶
The validity circuit uses the ParallelSum
gadget in Appendix A.3.
This gadget applies an arithmetic subcircuit to multiple inputs in parallel,
then sums the results. Along with the subcircuit, the
parallel-sum gadget is parameterized by an integer, denoted count
, specifying
how many times to call the subcircuit. It takes in a list of inputs and passes
them through to instances of the subcircuit in the same order. It returns the
sum of the subcircuit outputs.¶
Note that only the ParallelSum
gadget itself, and not its subcircuit,
participates in the FLP's wire recording during evaluation, gadget consistency
proofs, and proof validation, even though the subcircuit is provided to
ParallelSum
gadget as an implementation of the Gadget
interface.¶
The SumVec
validity circuit checks that the encoded measurement consists of
ones and zeros. Rather than use the PolyEval
gadget on each element, as in
the Sum
validity circuit, it instead uses Mul
subcircuits (Appendix A.1)
and "free" constant multiplication and addition gates to simultaneously
evaluate the same range check polynomial on each element, and multiply by a
constant. One of the two Mul
subcircuit inputs is equal to a measurement
element multiplied by a power of one of the elements of the joint randomness
vector, and the other is equal to the same measurement element minus one. These
Mul
subcircuits are evaluated by a ParallelSum
gadget, and the results are
added up both within the ParallelSum
gadget and after it.¶
The complete circuit is specified below:¶
class SumVec(Valid[list[int], list[int], F]): EVAL_OUTPUT_LEN = 1 length: int bits: int chunk_length: int field: type[F] def __init__(self, field: type[F], length: int, bits: int, chunk_length: int): """ Instantiate the `SumVec` circuit for measurements with `length` elements, each in the range `[0, 2^bits)`. """ self.field = field self.length = length self.bits = bits self.chunk_length = chunk_length self.GADGETS = [ParallelSum(Mul(), chunk_length)] self.GADGET_CALLS = [ (length * bits + chunk_length - 1) // chunk_length ] self.MEAS_LEN = length * bits self.OUTPUT_LEN = length self.JOINT_RAND_LEN = self.GADGET_CALLS[0] def encode(self, measurement: list[int]) -> list[F]: encoded = [] for val in measurement: encoded += self.field.encode_into_bit_vec( val, self.bits) return encoded def eval( self, meas: list[F], joint_rand: list[F], num_shares: int) -> list[F]: out = self.field(0) shares_inv = self.field(num_shares).inv() for i in range(self.GADGET_CALLS[0]): r = joint_rand[i] r_power = r inputs: list[Optional[F]] inputs = [None] * (2 * self.chunk_length) for j in range(self.chunk_length): index = i * self.chunk_length + j if index < len(meas): meas_elem = meas[index] else: meas_elem = self.field(0) inputs[j * 2] = r_power * meas_elem inputs[j * 2 + 1] = meas_elem - shares_inv r_power *= r out += self.GADGETS[0].eval( self.field, cast(list[F], inputs), ) return [out] def truncate(self, meas: list[F]) -> list[F]: truncated = [] for i in range(self.length): truncated.append(self.field.decode_from_bit_vec( meas[i * self.bits: (i + 1) * self.bits] )) return truncated def decode( self, output: list[F], _num_measurements: int) -> list[int]: return [x.int() for x in output]¶
ParallelSum
Chunk Length
The chunk_length
parameter provides a trade-off between the arity of the
ParallelSum
gadget (Appendix A.3) and the number of times the
gadget is called. The proof length is asymptotically minimized when the chunk
length is near the square root of the length of the encoded measurement.
However, the relationship between VDAF parameters and proof length is
complicated, involving two forms of rounding:¶
The circuit pads the inputs to its last ParallelSum
gadget call, up to
the chunk length.¶
The proof system rounds the degree of wire polynomials, determined by the number of times a gadget is called, up to the next power of two.¶
Therefore, the optimal choice of chunk_length
for a concrete measurement size
will vary, and must be found through trial and error. Setting chunk_length
equal to the square root of the appropriate measurement length will result in
proofs up to 50% larger than the optimal proof size.¶
Parameter | Value |
---|---|
field
|
Field128 (Table 3) |
Valid
|
Histogram(field, length, chunk_length) (this section) |
PROOFS
|
1
|
This variant of Prio3 allows for estimating the distribution of some quantity
by computing a simple histogram. Each measurement increments one histogram
bucket, out of a set of fixed buckets. (Bucket indexing begins at 0
.) For
example, the buckets might quantize the real numbers, and each measurement
would report the bucket that the corresponding client's real-numbered value
falls into. The aggregate result counts the number of measurements in each
bucket.¶
The validity circuit is denoted Histogram
. It has two parameters: length
,
the number of histogram buckets; and chunk_length
, which is used by a
circuit optimization described below. It is RECOMMENDED to set chunk_length
to an integer near the square root of length
(see
Section 7.4.3.1).¶
The measurement is encoded as a one-hot vector representing the bucket into which the measurement falls. The circuit checks for one-hotness in two steps, by checking that the encoded measurement consists of ones and zeros, and by checking that the sum of all elements in the encoded measurement is equal to one. The individual checks constitute the output of the circuit.¶
As in the SumVec
validity circuit (Section 7.4.3), the first part of the
validity circuit uses the ParallelSum
(Appendix A.3) gadget to
perform range checks while achieving a smaller proof size. The ParallelSum
gadget uses Mul
subcircuits (Appendix A.1) to evaluate a range check
polynomial on each element, and includes an additional constant multiplication.
One of the two Mul
subcircuit inputs is equal to a measurement element
multiplied by a power of an element of the joint randomness vector, and the
other is equal to the same measurement element minus one. The results are added
up both within the ParallelSum
gadget and after it.¶
class Histogram(Valid[int, list[int], F]): EVAL_OUTPUT_LEN = 2 field: type[F] length: int chunk_length: int def __init__(self, field: type[F], length: int, chunk_length: int): """ Instantiate an instance of the `Histogram` circuit with the given `length` and `chunk_length`. """ self.field = field self.length = length self.chunk_length = chunk_length self.GADGETS = [ParallelSum(Mul(), chunk_length)] self.GADGET_CALLS = [ (length + chunk_length - 1) // chunk_length] self.MEAS_LEN = self.length self.OUTPUT_LEN = self.length self.JOINT_RAND_LEN = self.GADGET_CALLS[0] def encode(self, measurement: int) -> list[F]: encoded = [self.field(0)] * self.length encoded[measurement] = self.field(1) return encoded def eval( self, meas: list[F], joint_rand: list[F], num_shares: int) -> list[F]: # Check that each bucket is one or zero. range_check = self.field(0) shares_inv = self.field(num_shares).inv() for i in range(self.GADGET_CALLS[0]): r = joint_rand[i] r_power = r inputs: list[Optional[F]] inputs = [None] * (2 * self.chunk_length) for j in range(self.chunk_length): index = i * self.chunk_length + j if index < len(meas): meas_elem = meas[index] else: meas_elem = self.field(0) inputs[j * 2] = r_power * meas_elem inputs[j * 2 + 1] = meas_elem - shares_inv r_power *= r range_check += self.GADGETS[0].eval( self.field, cast(list[F], inputs), ) # Check that the buckets sum to 1. sum_check = -shares_inv for b in meas: sum_check += b return [range_check, sum_check] def truncate(self, meas: list[F]) -> list[F]: return meas def decode( self, output: list[F], _num_measurements: int) -> list[int]: return [bucket_count.int() for bucket_count in output]¶
Parameter | Value |
---|---|
field
|
Field128 (Table 3) |
Valid
|
MultihotCountVec(field, length, max_weight, chunk_length) (this section) |
PROOFS
|
1
|
For this instance of Prio3, each measurement is a vector of Boolean
values, where the number of True
values is bounded. This provides a
functionality similar to Prio3Histogram except that more than one entry (or none
at all) may be non-zero. This allows Prio3MultihotCountVec to be composed with a
randomized response mechanism, like [EPK14], for providing differential
privacy. (For example, each Client would set each entry with some small
probability.)¶
The validity circuit is denoted MultihotCountVec
and has three parameters:
length
, the number of entries in the count vector; max_weight
, the maximum
number of True
entries (i.e., the weight must be at most max_weight
); and
chunk_length
, used the same way as in Section 7.4.3 and Section 7.4.4.¶
Validation works as follows. Let¶
The Client reports the weight of the count vector by adding offset
to it and
bit-encoding the result. Observe that only a weight of at most max_weight
can
be encoded with bits_for_weight
bits.¶
The verifier checks that each entry of the encoded measurement is a bit (i.e.,
either one or zero). It then decodes the reported weight and subtracts it from
offset + sum(count_vec)
, where count_vec
is the count vector. The result is
zero if and only if the reported weight is equal to the true weight. The two
checks constitute the output of the circuit. The complete circuit is defined
below.¶
class MultihotCountVec(Valid[list[bool], list[int], F]): EVAL_OUTPUT_LEN = 2 field: type[F] def __init__(self, field: type[F], length: int, max_weight: int, chunk_length: int): """ Instantiate an instance of the this circuit with the given `length`, `max_weight`, and `chunk_length`. Pre-conditions: - `length > 0` - `0 < max_weight` and `max_weight <= length` - `chunk_length > 0` """ self.field = field # Compute the number of bits to represent `max_weight`. self.bits_for_weight = max_weight.bit_length() self.offset = self.field( 2**self.bits_for_weight - 1 - max_weight) # Make sure `offset + length` doesn't overflow the field # modulus. Otherwise we may not correctly compute the sum # measurement vector entries during circuit evaluation. if self.field.MODULUS - self.offset.int() <= length: raise ValueError('length and max_weight are too large ' 'for the current field size') self.length = length self.max_weight = max_weight self.chunk_length = chunk_length self.GADGETS: list[Gadget[F]] = [ ParallelSum(Mul(), chunk_length), ] self.GADGET_CALLS = [ (length + self.bits_for_weight + chunk_length - 1) // chunk_length ] self.MEAS_LEN = self.length + self.bits_for_weight self.OUTPUT_LEN = self.length self.JOINT_RAND_LEN = self.GADGET_CALLS[0] def encode(self, measurement: list[bool]) -> list[F]: if len(measurement) != self.length: raise ValueError('invalid Client measurement length') # The first part is the vector of counters. count_vec = [self.field(int(x)) for x in measurement] # The second part is the reported weight. weight_reported = sum(count_vec, self.field(0)) encoded = [] encoded += count_vec encoded += self.field.encode_into_bit_vec( (self.offset + weight_reported).int(), self.bits_for_weight) return encoded def eval( self, meas: list[F], joint_rand: list[F], num_shares: int) -> list[F]: # Check that each entry in the input vector is one or zero. range_check = self.field(0) shares_inv = self.field(num_shares).inv() for i in range(self.GADGET_CALLS[0]): r = joint_rand[i] r_power = r inputs: list[Optional[F]] inputs = [None] * (2 * self.chunk_length) for j in range(self.chunk_length): index = i * self.chunk_length + j if index < len(meas): meas_elem = meas[index] else: meas_elem = self.field(0) inputs[j * 2] = r_power * meas_elem inputs[j * 2 + 1] = meas_elem - shares_inv r_power *= r range_check += self.GADGETS[0].eval( self.field, cast(list[F], inputs), ) # Check that the weight `offset` plus the sum of the counters # is equal to the value claimed by the Client. count_vec = meas[:self.length] weight = sum(count_vec, self.field(0)) weight_reported = \ self.field.decode_from_bit_vec(meas[self.length:]) weight_check = self.offset*shares_inv + weight - \ weight_reported return [range_check, weight_check] def truncate(self, meas: list[F]) -> list[F]: return meas[:self.length] def decode( self, output: list[F], _num_measurements: int) -> list[int]: return [bucket_count.int() for bucket_count in output]¶
This section specifies Poplar1, a VDAF for the following task. Each Client
holds a bit-string of length BITS
and the Collector chooses a sequence of
L
-bit strings, where L <= BITS
. We will refer to the latter as the
"candidate prefixes". The goal is to count how many of the Clients' inputs
begin with each candidate prefix.¶
This functionality is the core component of the heavy hitters protocol of
[BBCGGI21]. The goal of this protocol is to compute the subset of inputs held
by at least T
Clients for some threshold T
. It invokes Poplar1 as follows:¶
Each Client shards its string into secret shares and uploads one share to each of the Aggregators.¶
The Collector picks an initial set of candidate prefixes, say 0
and 1
,
and sends them to the Aggregators.¶
The Aggregators run VDAF preparation and aggregation on each of the reports and send their aggregate shares to the Collector.¶
The Collector unshards the aggregate result, which consists of the hit count
for each candidate prefix. For each prefix p
with hit count at least T
,
the Collector adds p || 0
and p || 1
to the next generation of
candidate prefixes and repeats Step 2.¶
Poplar1 is constructed from an "Incremental Distributed Point Function (IDPF)", a primitive described by [BBCGGI21] that generalizes the notion of a Distributed Point Function (DPF) [GI14]. Briefly, a DPF is used to distribute the computation of a "point function", a function that evaluates to zero on every input except at a programmable "point". The computation is distributed in such a way that no one party knows either the point or what it evaluates to.¶
An IDPF generalizes this "point" to a path on a full binary tree from the root to one of the leaves. It is evaluated on an "index" representing a unique node of the tree. If the node is on the programmed path, then the function evaluates to a non-zero value; otherwise it evaluates to zero. This structure allows an IDPF to provide the functionality required for the above protocol: to compute the hit count for an index, just evaluate each set of IDPF shares at that index and add up the results.¶
Consider the sub-tree constructed from a set of input strings and a target
threshold T
by including all indices with hit count at least T
. We shall
refer to this structure as the "prefix tree" for the batch of measurements and
target threshold. To compute the T
-heavy-hitters for the batch, the
Aggregators and Collector first compute the prefix tree, then extract the heavy
hitters from the leaves of this tree. Note that the prefix tree leaks more
information about the set than the heavy hitters themselves; see
Section 9.4 for more discussion.¶
Poplar1 composes an IDPF with the arithmetic sketch of [BBCGGI21], Section 4.2. (The paper calls this a "secure sketch", but the underlying technique was later generalized in [BBCGGI23], where it is called "arithmetic sketching".) The sketch ensures that evaluating a set of input shares on a set of unique candidate prefixes results in shares of a zero vector or a "one-hot" vector, i.e., a vector that is zero everywhere except for in at most one position. Moreover, the value at that position should be one.¶
The remainder of this section is structured as follows. The syntax of IDPFs is defined in Section 8.1. The Poplar1 VDAF is defined in Section 8.2 in terms of a generic IDPF. A specification of the IDPF of [BBCGGI21] is given in Section 8.3. Test vectors for Poplar1 can be found in Appendix C.¶
An IDPF is defined over a domain of size 2^BITS
, where BITS
is a constant.
Indices into the IDPF tree are bit strings. (In Poplar1, each Client's bit
string is an index; see Section 8.1.1 for details.) The Client
specifies an index alpha
and a vector of values beta
, one for each "level"
L
in the range [0, BITS)
. The key generation algorithm generates one IDPF
"key" for each Aggregator. When evaluated at level L
and index prefix
, each
IDPF key returns an additive share of beta[L]
if prefix
is the L
-bit
prefix of alpha
and shares of zero otherwise.¶
Each of the programmed points beta
is a vector of elements of some finite
field. We distinguish two types of fields: one for inner nodes (denoted
FieldInner
), and one for leaf nodes (FieldLeaf
). (Our instantiation of
Poplar1 (Section 8.2) will use a much larger field for leaf nodes
than for inner nodes. This is to ensure the IDPF is "extractable" as defined in
[BBCGGI21], Definition 1. See Section 9.5 for details.)¶
A concrete IDPF defines the types and parameters enumerated in Table 14.
In the remainder we write Output
as shorthand for the type
list[list[FieldInner]] | list[list[FieldLeaf]]
. (This type denotes either a
vector of inner node field elements or leaf node field elements.) The scheme is
comprised of the following algorithms:¶
idpf.gen(alpha: tuple[bool, ...], beta_inner: list[list[FieldInner]], beta_leaf:
list[FieldLeaf], ctx: bytes, nonce: bytes, rand: bytes) -> tuple[PublicShare,
list[bytes]]
is the IDPF-key generation algorithm. Its inputs are the index
alpha
, the values beta
, the application context, and the report nonce.¶
The output is a public part (of type PublicShare
) that is sent to each
Aggregator and a vector of private IDPF keys, one for each Aggregator. The
nonce and application context are used to derive the fixed AES key for
XofFixedKeyAes128 (Section 6.2.2). Looking ahead, this key is used
for extending a node's seed into the seeds for the child nodes at each level
of the tree; see Section 8.3.¶
Pre-conditions:¶
alpha
MUST have length BITS
.¶
beta_inner
MUST have length BITS - 1
.¶
beta_inner[level]
MUST have length VALUE_LEN
for each level
in
the range [0, BITS - 1)
.¶
beta_leaf
MUST have length VALUE_LEN
.¶
rand
MUST be generated by a CSPRNG and have length RAND_SIZE
.¶
nonce
MUST be generated by a CSPRNG (see Section 9.2 for
details) and have length idpf.NONCE_SIZE
.¶
Post-conditions:¶
The number of IDPF keys MUST be idpf.SHARES
.¶
idpf.eval(agg_id: int, public_share: PublicShare, key: bytes, level: int,
prefixes: Sequence[tuple[bool, ...]], ctx: bytes, nonce: bytes) -> Output
is
the IDPF-key evaluation algorithm run by each Aggregator. Its inputs are the
Aggregator's unique identifier, the public share distributed to all of the
Aggregators, the Aggregator's IDPF key, the "level" at which to evaluate the
IDPF, the sequence of candidate prefixes, the application context, and the
report nonce. It returns the share of the value corresponding to each
candidate prefix.¶
Pre-conditions:¶
agg_id
MUST be in the range [0, idpf.SHARES)
and match the index of
key
in the sequence of IDPF keys output by the Client.¶
level
MUST be in the range [0, BITS)
.¶
Each prefix MUST be distinct and have length level + 1
.¶
The length of the nonce MUST be idpf.NONCE_SIZE
.¶
Post-conditions:¶
In addition, the IDPF provides the following method:¶
def current_field( self, level: int) -> type[FieldInner] | type[FieldLeaf]: if level < self.BITS - 1: return self.field_inner return self.field_leaf¶
Finally, an implementation note. The interface for IDPFs specified here is stateless, in the sense that there is no state carried between IDPF evaluations. This is to align the IDPF syntax with the VDAF abstraction boundary, which does not include shared state across VDAF evaluations. In practice, of course, it will often be beneficial to expose a stateful API for IDPFs and carry the state across evaluations. See Section 8.3 for details.¶
Parameter | Description |
---|---|
SHARES: int
|
Number of IDPF keys output by IDPF-key generator. |
BITS: int
|
Length in bits of each input string. |
VALUE_LEN: int
|
Number of field elements of each output value. |
RAND_SIZE: int
|
Size of the random string consumed by the IDPF-key generator. |
NONCE_SIZE: int
|
Size of the random nonce generated by the Client. |
KEY_SIZE: int
|
Size in bytes of each IDPF key. |
FieldInner
|
Implementation of Field (Section 6.1) used for values of inner nodes. |
FieldLeaf
|
Implementation of Field used for values of leaf nodes. |
PublicShare
|
Type of public share for this IDPF. |
Output
|
Alias of list[list[FieldInner]] | list[list[FieldLeaf]] . |
FieldVec
|
Alias of list[FieldInner] | list[FieldLeaf].
|
How data are represented as IDPF indices is up to the application. When the inputs are fixed-length byte strings, the most natural choice of representation is as a bit string formed from all the bits of the byte string, first ordered by byte position, then ordered from most significant bit to least significant bit within each byte. This ensures that, when a byte string is a prefix of another, so too is its corresponding index. (Index prefixes are defined in Section 8.1.) For example,¶
Byte string: 01 02 Bit string: 00000001 00000010¶
is a prefix of¶
Byte string: 01 02 03 Bit string: 00000001 00000010 00000011¶
Additionally, lexicographic ordering is preserved by this mapping from a byte string to a bit string.¶
When the inputs are variable length, it is necessary to pad each input to some
fixed length. Further, the padding scheme must be non-ambiguous. For example,
each input could be padded with b"\x01"
followed by as many b"\x00"
bytes
as needed.¶
This section specifies Poplar1
, an implementation of the Vdaf
interface
(Section 5). It is defined in terms of the Idpf
implementation of
Section 8.3 with SHARES == 2
and VALUE_LEN == 2
and
XofTurboShake128
as specified in Section 6.2.1. The associated
constants and types required by the Vdaf
interface are defined in
Table 15. The methods required for sharding, preparation, aggregation,
and unsharding are described in the remaining subsections. These methods make
use of constants defined in Table 16.¶
Parameter | Value |
---|---|
idpf
|
As specified in Section 8.3. |
xof
|
XofTurboShake128 (Section 6.2.1) |
VERIFY_KEY_SIZE
|
xof.SEED_SIZE
|
RAND_SIZE
|
xof.SEED_SIZE * 3 + idpf.RAND_SIZE
|
NONCE_SIZE
|
16
|
ROUNDS
|
2
|
SHARES
|
2
|
Measurement
|
tuple[bool, ...]
|
AggParam
|
tuple[int, Sequence[tuple[bool, ...]]]
|
PublicShare
|
As defined by idpf . |
InputShare
|
tuple[bytes, bytes, list[FieldInner], list[FieldLeaf]]
|
OutShare
|
FieldVec
|
AggShare
|
FieldVec
|
AggResult
|
list[int]
|
PrepState
|
tuple[bytes, int, FieldVec]
|
PrepShare
|
FieldVec
|
PrepMessage
|
Optional[FieldVec]
|
Variable | Value |
---|---|
USAGE_SHARD_RAND: int | 1 |
USAGE_CORR_INNER: int | 2 |
USAGE_CORR_LEAF: int | 3 |
USAGE_VERIFY_RAND: int | 4 |
The aggregation parameter encodes a sequence of candidate prefixes. When an
Aggregator receives an input share from the Client, it begins by evaluating its
IDPF share on each candidate prefix, recovering a data_share
and auth_share
for each. The Aggregators use these and the correlation shares provided by the
Client to verify that the sequence of data_share
values are additive shares of
a zero vector or a one-hot vector.¶
Aggregators MUST ensure the candidate prefixes are all unique and appear in
lexicographic order. (This is enforced in the definition of is_valid()
below.) Uniqueness is necessary to ensure the refined measurement (i.e., the sum
of the output shares) is in fact a one-hot vector. Otherwise, sketch
verification might fail, causing the Aggregators to erroneously reject a report
that is actually valid. Note that enforcing the order is not strictly necessary,
but this does allow uniqueness to be determined more efficiently.¶
def prep_init( self, verify_key: bytes, ctx: bytes, agg_id: int, agg_param: Poplar1AggParam, nonce: bytes, public_share: Poplar1PublicShare, input_share: Poplar1InputShare) -> tuple[ Poplar1PrepState, FieldVec]: (level, prefixes) = agg_param (key, corr_seed, corr_inner, corr_leaf) = input_share field = self.idpf.current_field(level) # Evaluate the IDPF key at the given set of prefixes. value = self.idpf.eval( agg_id, public_share, key, level, prefixes, ctx, nonce) # Get shares of the correlated randomness for evaluating the # Aggregator's share of the sketch. if level < self.idpf.BITS - 1: corr_xof = self.xof( corr_seed, self.domain_separation_tag(USAGE_CORR_INNER, ctx), byte(agg_id) + nonce, ) # Fast-forward the XOF state to the current level. corr_xof.next_vec(field, 3 * level) else: corr_xof = self.xof( corr_seed, self.domain_separation_tag(USAGE_CORR_LEAF, ctx), byte(agg_id) + nonce, ) (a_share, b_share, c_share) = corr_xof.next_vec(field, 3) if level < self.idpf.BITS - 1: (A_share, B_share) = cast( list[Field], corr_inner[2 * level:2 * (level + 1)], ) else: (A_share, B_share) = cast(list[Field], corr_leaf) # Evaluate the Aggregator's share of the sketch. These are # called the "masked input values" [BBCGGI21, Appendix C.4]. verify_rand_xof = self.xof( verify_key, self.domain_separation_tag(USAGE_VERIFY_RAND, ctx), nonce + to_be_bytes(level, 2), ) verify_rand = cast( list[Field], verify_rand_xof.next_vec(field, len(prefixes)), ) sketch_share = [a_share, b_share, c_share] out_share = [] for (i, r) in enumerate(verify_rand): data_share = cast(Field, value[i][0]) auth_share = cast(Field, value[i][1]) sketch_share[0] += data_share * r sketch_share[1] += data_share * r ** 2 sketch_share[2] += auth_share * r out_share.append(data_share) prep_mem = [A_share, B_share, field(agg_id)] + out_share return ( ( b'evaluate sketch', level, cast(FieldVec, prep_mem), ), cast(FieldVec, sketch_share), ) def prep_next( self, _ctx: bytes, prep_state: Poplar1PrepState, prep_msg: Optional[FieldVec] ) -> tuple[Poplar1PrepState, FieldVec] | FieldVec: prev_sketch = cast(list[Field], prep_msg) (step, level, prep_mem) = prep_state if step == b'evaluate sketch': if prev_sketch is None: raise ValueError('expected value, got none') elif len(prev_sketch) != 3: raise ValueError('incorrect sketch length') A_share = cast(Field, prep_mem[0]) B_share = cast(Field, prep_mem[1]) agg_id = cast(Field, prep_mem[2]) prep_mem = prep_mem[3:] sketch_share = [ agg_id * (prev_sketch[0] ** 2 - prev_sketch[1] - prev_sketch[2]) + A_share * prev_sketch[0] + B_share ] return cast( tuple[Poplar1PrepState, FieldVec], ( ( b'reveal sketch', level, prep_mem, ), sketch_share, ) ) elif step == b'reveal sketch': if prev_sketch is None: return prep_mem # Output shares else: raise ValueError('invalid prep message') raise ValueError('invalid prep state') def prep_shares_to_prep( self, _ctx: bytes, agg_param: Poplar1AggParam, prep_shares: list[FieldVec]) -> Optional[FieldVec]: if len(prep_shares) != 2: raise ValueError('incorrect number of prep shares') (level, _) = agg_param field = self.idpf.current_field(level) sketch = vec_add( cast(list[Field], prep_shares[0]), cast(list[Field], prep_shares[1]), ) if len(sketch) == 3: return cast(FieldVec, sketch) elif len(sketch) == 1: if sketch == field.zeros(1): # In order to reduce communication overhead, let `None` # denote a successful sketch verification. return None else: raise ValueError('sketch verification failed') else: raise ValueError('incorrect sketch length')¶
Aggregation parameters are valid for a given input share if no aggregation parameter with the same level has been used with the same input share before. The whole preparation phase MUST NOT be run more than once for a given combination of input share and level. This function checks that candidate prefixes are unique and lexicographically sorted, checks that levels are increasing between calls, and also enforces that the prefixes at each level are suffixes of the previous level's prefixes.¶
def is_valid( self, agg_param: Poplar1AggParam, previous_agg_params: list[Poplar1AggParam]) -> bool: """ Checks that candidate prefixes are unique and lexicographically sorted, checks that levels are increasing between calls, and also enforces that the prefixes at each level are suffixes of the previous level's prefixes. """ (level, prefixes) = agg_param # Ensure that candidate prefixes are all unique and appear in # lexicographic order. for i in range(1, len(prefixes)): if prefixes[i - 1] >= prefixes[i]: return False if len(previous_agg_params) < 1: return True (last_level, last_prefixes) = previous_agg_params[-1] last_prefixes_set = set(last_prefixes) # Check that level increased. if level <= last_level: return False # Check that prefixes are suffixes of the last level's prefixes. for prefix in prefixes: last_prefix = get_ancestor(prefix, last_level) if last_prefix not in last_prefixes_set: # Current prefix not a suffix of last level's prefixes. return False return True def get_ancestor( index: tuple[bool, ...], level: int) -> tuple[bool, ...]: """ Helper function to determine the prefix of `index` at `level`. """ return index[:level + 1]¶
Aggregation involves simply adding up the output shares.¶
def agg_init(self, agg_param: Poplar1AggParam) -> FieldVec: (level, prefixes) = agg_param field = self.idpf.current_field(level) return field.zeros(len(prefixes)) def agg_update(self, agg_param: Poplar1AggParam, agg_share: FieldVec, out_share: FieldVec) -> FieldVec: a = cast(list[Field], agg_share) o = cast(list[Field], out_share) return cast(FieldVec, vec_add(a, o)) def merge(self, agg_param: Poplar1AggParam, agg_shares: list[FieldVec]) -> FieldVec: (level, prefixes) = agg_param field = self.idpf.current_field(level) agg = cast(list[Field], field.zeros(len(prefixes))) for agg_share in agg_shares: agg = vec_add(agg, cast(list[Field], agg_share)) return cast(FieldVec, agg)¶
Finally, the Collector unshards the aggregate result by adding up the aggregate shares.¶
def unshard( self, agg_param: Poplar1AggParam, agg_shares: list[FieldVec], _num_measurements: int) -> list[int]: agg = self.merge(agg_param, agg_shares) return [x.int() for x in agg]¶
This section defines serialization formats for messages exchanged over the
network while executing Poplar1
. Messages are defined in the presentation
language of TLS as defined in Section 3 of [RFC8446].¶
Let poplar1
be an instance of Poplar1
. In the remainder we use Fi
as an
alias for poplar1.idpf.field_inner.ENCODED_SIZE
, Fl
as an alias for
poplar1.idpf.field_leaf.ENCODED_SIZE
, and B
as an alias for
poplar1.idpf.BITS
.¶
Elements of the inner field are encoded in little-endian byte order (as defined in Section 6.1) and are represented as follows:¶
opaque Poplar1FieldInner[Fi];¶
Likewise, elements of the leaf field are encoded in little-endian byte order (as defined in Section 6.1) and are represented as follows:¶
opaque Poplar1FieldLeaf[Fl];¶
Likewise, the structure of the prep message for Poplar1 depends on the sketching round and field. For the first round and inner field:¶
struct { Poplar1FieldInner[Fi * 3]; } Poplar1PrepMessageRoundOneInner;¶
For the first round and leaf field:¶
struct { Poplar1FieldLeaf sketch[Fl * 3]; } Poplar1PrepMessageRoundOneLeaf;¶
Note that these messages have the same structures as the prep shares for the first round.¶
The second-round prep message is the empty string. This is because the sketch shares are expected to sum to a particular value if the output shares are valid; we represent a successful preparation with the empty string and otherwise return an error.¶
The aggregation parameter is encoded as follows:¶
struct { uint16_t level; uint32_t num_prefixes; opaque encoded_prefixes[prefixes_len]; } Poplar1AggParam;¶
The fields in this struct are: level
, the level of the IDPF tree of each
prefixes; num_prefixes
, the number of prefixes to evaluate; and
encoded_prefixes
, the sequence of prefixes encoded into a byte string of
length prefixes_len
. Each prefix is packed into a byte string, with the bits
assigned in MSB-to-LSB order, and then the byte strings for each prefix are
concatenated together. The prefixes are encoded with the following procedure:¶
prefixes_len = ((level + 1) + 7) // 8 * len(prefixes) encoded_prefixes = bytearray() for prefix in prefixes: for chunk in itertools.batched(prefix, 8): byte_out = 0 for (bit_position, bit) in enumerate(chunk): byte_out |= bit << (7 - bit_position) encoded_prefixes.append(byte_out)¶
Decoding involves the following procedure:¶
prefixes = [] bytes_per_prefix = ((level + 1) + 7) // 8 for chunk in itertools.batched(encoded_prefixes, bytes_per_prefix): prefix = [] for i in range(level + 1): byte_index = i // 8 bit_offset = 7 - (i % 8) bit = (chunk[byte_index] >> bit_offset) & 1 != 0 prefix.append(bit) prefixes.append(tuple(prefix))¶
Implementation note: the aggregation parameter includes the level of the IDPF tree and the sequence of indices to evaluate. For implementations that perform per-report caching across executions of the VDAF, this may be more information than is strictly needed. In particular, it may be sufficient to convey which indices from the previous execution will have their children included in the next. This would help reduce communication overhead.¶
In this section we specify a concrete IDPF suitable for instantiating Poplar1.
The constant and type definitions required by the Idpf
interface are given in
Table 17.¶
Our IDPF requires an XOF for deriving the output shares, as well as a variety of other artifacts used internally. For performance reasons, we instantiate this object using XofFixedKeyAes128 (Section 6.2.2) wherever possible. See Section 9.6 for security considerations.¶
Parameter | Value |
---|---|
xof
|
XofFixedKeyAes128 (Section 6.2.2) |
SHARES
|
2
|
BITS
|
Any positive integer. |
VALUE_LEN
|
Any positive integer. |
KEY_SIZE
|
xof.SEED_SIZE
|
FieldInner
|
Field64 (Table 3) |
FieldLeaf
|
Field255 (Table 3) |
At a high level, the IDPF maps a key generator's input (alpha, beta_1, ...,
beta_BITS)
onto a binary tree with BITS+1
levels, where each edge going from
a parent node to a left child is labeled 0
, and each right edge is labeled
1
. Then each leaf node corresponds to a bit string of length BITS
, where the
labels on the path from the root to x
contain the individual bits. Finally,
all nodes in the tree have an assigned value, with the nodes on the path
from the root to alpha
having values beta_1, ..., beta_BITS
, and all other
nodes having value 0
.¶
The IDPF construction now boils down to secret-sharing the values at each node
of that tree in an efficient way. Note that explicitly representing the tree
requires O(2^BITS)
space, so the generator cannot just compute additive shares
of it and send them to the two evaluators. Instead, the evaluators will
re-generate shares of values at selected nodes of the tree using a XOF
(Section 6.2).¶
The basic observation is that if both evaluators have the same seed s
of
length KEY_SIZE
, then expanding s
using a XOF will also result in the same
expansion. If we set the length of the XOF expansion to 2*KEY_SIZE
, it can
then be split again into two seeds s_l
, s_r
, that can again serve as XOF
seeds. Now if we view seeds as XOR-shares of integers, and if evaluators have
the same seed at the root of the tree, then their expanded trees will form a
secret-shared tree of zeros. The actual construction will additionally use a
convert()
function before each expansion, which maps seeds into the
appropriate output domain (see Section 8.3.4), generating
a new seed for the next level in the process.¶
The open task now is to ensure that evaluators have different seeds at nodes
that lie on the path to alpha
, while having the same seeds on all other nodes.
This is done using so-called "correction words" included in the public share.
The correction words are conditionally added to the XOF output by both
evaluators. The condition here is a secret-shared bit, called a "control bit",
which indicates whether the current node is on the path to alpha
or not. On
the path, the control bits add up to 1
, meaning only one evaluator will add
the correction word to its XOF output. Off the path, either none or both
evaluators add the correction word, and so the seeds at the next level stay the
same.¶
What remains is to turn the (now pseudorandom) values on the path to alpha
into the desired beta
values. This is done by including "value correction
words" in the public share, which are chosen such that when added with the
pseudorandom shares at the i
th node on the path to alpha
, they add up to
shares of beta_i
.¶
In the following two sections we describe the algorithms for key generation in full detail.¶
The description of the IDPF-key generation algorithm makes use of auxiliary
functions extend()
and convert()
defined in
Section 8.3.4.¶
def gen( self, alpha: tuple[bool, ...], beta_inner: list[list[Field64]], beta_leaf: list[Field255], ctx: bytes, nonce: bytes, rand: bytes) -> tuple[list[CorrectionWord], list[bytes]]: if len(alpha) != self.BITS: raise ValueError("incorrect alpha length") if len(beta_inner) != self.BITS - 1: raise ValueError("incorrect beta_inner length") if len(rand) != self.RAND_SIZE: raise ValueError("incorrect rand size") if len(nonce) != self.NONCE_SIZE: raise ValueError("incorrect nonce size") key = [ rand[:XofFixedKeyAes128.SEED_SIZE], rand[XofFixedKeyAes128.SEED_SIZE:], ] seed = key.copy() ctrl = [False, True] public_share = [] for level in range(self.BITS): bit = alpha[level] keep = int(bit) lose = 1 - keep (s0, t0) = self.extend(level, seed[0], ctx, nonce) (s1, t1) = self.extend(level, seed[1], ctx, nonce) seed_cw = xor(s0[lose], s1[lose]) ctrl_cw = ( t0[0] ^ t1[0] ^ (not bit), t0[1] ^ t1[1] ^ bit, ) # Implementation note: these conditional XORs and # input-dependent array indices should be replaced with # constant-time selects in practice in order to reduce # leakage via timing side channels. if ctrl[0]: x0 = xor(s0[keep], seed_cw) ctrl[0] = t0[keep] ^ ctrl_cw[keep] else: x0 = s0[keep] ctrl[0] = t0[keep] if ctrl[1]: x1 = xor(s1[keep], seed_cw) ctrl[1] = t1[keep] ^ ctrl_cw[keep] else: x1 = s1[keep] ctrl[1] = t1[keep] (seed[0], w0) = self.convert(level, x0, ctx, nonce) (seed[1], w1) = self.convert(level, x1, ctx, nonce) if level < self.BITS - 1: b = cast(list[Field], beta_inner[level]) else: b = cast(list[Field], beta_leaf) if len(b) != self.VALUE_LEN: raise ValueError( "length of beta must match the value length" ) w_cw = vec_add(vec_sub(b, w0), w1) # Implementation note: this conditional negation should be # replaced with a constant time select or a constant time # multiplication in practice in order to reduce leakage via # timing side channels. if ctrl[1]: for i in range(len(w_cw)): w_cw[i] = -w_cw[i] public_share.append((seed_cw, ctrl_cw, w_cw)) return (public_share, key)¶
The description of the IDPF-evaluation algorithm makes use of auxiliary
functions extend()
and convert()
defined in
Section 8.3.4.¶
def eval( self, agg_id: int, public_share: list[CorrectionWord], key: bytes, level: int, prefixes: Sequence[tuple[bool, ...]], ctx: bytes, nonce: bytes) -> list[list[Field64]] | list[list[Field255]]: if agg_id not in range(self.SHARES): raise ValueError('aggregator id out of range') if level not in range(self.BITS): raise ValueError('level out of range') if len(set(prefixes)) != len(prefixes): raise ValueError('prefixes must be unique') out_share = [] for prefix in prefixes: if len(prefix) != level + 1: raise ValueError('incorrect prefix length') # The Aggregator's output share is the value of a node of # the IDPF tree at the given `level`. The node's value is # computed by traversing the path defined by the candidate # `prefix`. Each node in the tree is represented by a seed # (`seed`) and a control bit (`ctrl`). seed = key ctrl = bool(agg_id) y: FieldVec for current_level in range(level + 1): bit = int(prefix[current_level]) # Implementation note: typically the current round of # candidate prefixes would have been derived from # aggregate results computed during previous rounds. # For example, when using the IDPF to compute heavy # hitters, a string whose hit count exceeded the # given threshold in the last round would be the # prefix of each `prefix` in the current round. (See # [BBCGGI21, Section 5.1].) In this case, part of the # path would have already been traversed. # # Re-computing nodes along previously traversed paths is # wasteful. Implementations can eliminate this added # complexity by caching nodes (i.e., `(seed, ctrl)` # pairs) output by previous calls to `eval_next()`. (seed, ctrl, y) = self.eval_next( seed, ctrl, public_share[current_level], current_level, bit, ctx, nonce, ) if agg_id == 0: out_share.append(cast(list[Field], y)) else: out_share.append(vec_neg(cast(list[Field], y))) return cast( list[list[Field64]] | list[list[Field255]], out_share, ) def eval_next( self, prev_seed: bytes, prev_ctrl: bool, correction_word: CorrectionWord, level: int, bit: int, ctx: bytes, nonce: bytes) -> tuple[bytes, bool, FieldVec]: """ Compute the next node in the IDPF tree along the path determined by a candidate prefix. The next node is determined by `bit`, the bit of the prefix corresponding to the next level of the tree. """ seed_cw = correction_word[0] ctrl_cw = correction_word[1] w_cw = cast(list[Field], correction_word[2]) (s, t) = self.extend(level, prev_seed, ctx, nonce) # Implementation note: these conditional operations and # input-dependent array indices should be replaced with # constant-time selects in practice in order to reduce leakage # via timing side channels. if prev_ctrl: s[0] = xor(s[0], seed_cw) s[1] = xor(s[1], seed_cw) t[0] ^= ctrl_cw[0] t[1] ^= ctrl_cw[1] next_ctrl = t[bit] convert_output = self.convert(level, s[bit], ctx, nonce) next_seed = convert_output[0] y = cast(list[Field], convert_output[1]) # Implementation note: this conditional addition should be # replaced with a constant-time select in practice in order to # reduce leakage via timing side channels. if next_ctrl: for i in range(len(y)): y[i] += w_cw[i] return (next_seed, next_ctrl, cast(FieldVec, y))¶
def extend( self, level: int, seed: bytes, ctx: bytes, nonce: bytes) -> tuple[list[bytes], list[bool]]: xof = self.current_xof( level, seed, format_dst(1, 0, 0) + ctx, nonce, ) s = [ bytearray(xof.next(self.KEY_SIZE)), bytearray(xof.next(self.KEY_SIZE)), ] # Use the least significant bits as the control bit correction, # and then zero it out. This gives effectively 127 bits of # security, but reduces the number of AES calls needed by 1/3. t = [bool(s[0][0] & 1), bool(s[1][0] & 1)] s[0][0] &= 0xFE s[1][0] &= 0xFE return ([bytes(s[0]), bytes(s[1])], t) def convert( self, level: int, seed: bytes, ctx: bytes, nonce: bytes) -> tuple[bytes, FieldVec]: xof = self.current_xof( level, seed, format_dst(1, 0, 1) + ctx, nonce, ) next_seed = xof.next(self.KEY_SIZE) field = self.current_field(level) w = xof.next_vec(field, self.VALUE_LEN) return (next_seed, cast(FieldVec, w)) def current_xof(self, level: int, seed: bytes, dst: bytes, nonce: bytes) -> Xof: if level < self.BITS-1: return XofFixedKeyAes128(seed, dst, nonce) return XofTurboShake128(seed, dst, nonce)¶
VDAFs (Section 5) have two essential security goals:¶
Privacy: an attacker that controls the Collector and a subset of Clients and Aggregators learns nothing about the measurements of honest Clients beyond what it can deduce from the aggregate result. We assume the attacker controls the entire network except for channels between honest Clients and honest Aggregators. In particular, it cannot forge or prevent transmission of messages on these channels.¶
Robustness: an attacker that controls a subset of Clients cannot cause the Collector to compute anything other than the aggregate of the measurements of honest Clients, plus valid measurements from some of the attacker-controlled Clients. We assume the attacker eavesdrops on the network but does not control transmission of messages between honest parties.¶
Formal definitions of privacy and robustness can be found in [DPRS23]. A VDAF is the core cryptographic primitive of a protocol that achieves the above privacy and robustness goals. It is not sufficient on its own, however. The application will need to assure a few security properties, for example:¶
Securely distributing the long-lived parameters, in particular the verification key.¶
Establishing secure channels:¶
Enforcing the non-collusion properties required of the specific VDAF in use.¶
In such an environment, a VDAF provides the high-level privacy property described above: the Collector learns only the aggregate result, and nothing about individual measurements aside from what can be inferred from the aggregate result. The Aggregators learn neither individual measurements nor the aggregate result. The Collector is assured that the aggregate statistic accurately reflects the inputs as long as the Aggregators correctly executed their role in the VDAF.¶
On their own, VDAFs do not provide:¶
Mitigation of Sybil attacks [Dou02]. In this attack, the adversary observes a subset of input shares transmitted by a Client it is interested in. It allows the input shares to be processed, but corrupts and picks bogus measurements for the remaining Clients. Applications can guard against these risks by adding additional controls on report submission, such as Client authentication and rate limits.¶
Differential privacy [Dwo06]. Depending on the distribution of the measurements, the aggregate result itself can still leak a significant amount of information about an individual measurement or the person that generated it.¶
Robustness in the presence of a malicious Aggregator. An Aggregator can, without detection, manipulate the aggregate result by modifying its own aggregate share.¶
Guaranteed output delivery [GSZ20]. An attacker that controls transmission of messages between honest parties can prevent computation of the aggregate result by dropping messages.¶
The Aggregators are responsible for exchanging the verification key in advance of executing the VDAF. Any procedure is acceptable as long as the following conditions are met:¶
To ensure robustness of the computation, the Aggregators MUST NOT reveal the verification key to the Clients. Otherwise, a malicious Client might be able to exploit knowledge of this key to craft an invalid report that would be accepted by the Aggregators.¶
To ensure privacy of the measurements, the Aggregators MUST commit to the verification key prior to processing reports generated by Clients. Otherwise, the attacker may be able to craft a verification key that, for a given report, causes an honest Aggregator to leak information about the measurement during preparation.¶
Meeting these requirements is relatively straightforward. For example, the Aggregators may designate one of their peers to generate the verification key and distribute it to the others. To assure Clients of key commitment, the Clients and (honest) Aggregators SHOULD bind the verification key to the application context. For instance, the "task ID" of DAP [DAP] could be set to the hash of the verification key; then as long as honest Aggregators only consume reports for the task indicated by the Client, forging a new key after the fact would reduce to finding collisions in the underlying hash function. (Keeping the key secret from the Clients would require the hash function to be one-way.) However, since rotating the key implies rotating the task ID, this scheme would not allow key rotation over the lifetime of a task.¶
The sharding and preparation steps of VDAF execution depend on a nonce associated with the Client's report. To ensure privacy of the underlying measurement, the Client MUST generate this nonce using a CSPRNG. This is required in order to leverage security analysis for the privacy definition of [DPRS23], which assumes the nonce is chosen at random prior to generating the report. Uniqueness of the nonce is not sufficient because the verification key is controlled by the attacker.¶
Applications will need to protect against replay attacks to prevent disallowed re-use of reports (see Section 9.4). Furthermore, in applications that aim to achieve differential privacy, it is necessary to limit how much each party contributes to a single batch or multiple batches. It is RECOMMENDED that the nonce generated by the Client be used by the Aggregators for replay protection.¶
As described in Section 4.3 and Section 5.3 respectively, DAFs and VDAFs may impose restrictions on the re-use of reports. For Prio3, reports should only be aggregated once; for Poplar1, reports may be aggregated multiple times, but never twice at the same level of the tree. Otherwise, we risk re-using correlated randomness, which might compromise confidentiality of the Client's measurement.¶
Higher level applications that use DAFs or VDAFs MUST enforce aggregation
parameter validity. In particular, prior to beginning preparation with an
aggregation parameter provided by the Collector, they MUST invoke is_valid()
to decide if the parameter is valid given the sequence of previously accepted
parameters.¶
Note that aggregating a batch of reports multiple times, even with a valid sequence of aggregation parameters, can result in information leakage beyond what is used by the application.¶
For example, when Poplar1 is used for heavy hitters, the Aggregators learn not only the heavy hitters themselves, but also the prefix tree (as defined in Section 8) computed along the way. Indeed, this leakage is inherent to any construction that uses an IDPF (Section 8.1) in the same way. Depending on the distribution of the measurements, the prefix tree can leak a significant amount of information about unpopular inputs. For instance, it is possible (though perhaps unlikely) for a large set of non-heavy-hitter values to share a common prefix, which would be leaked by a prefix tree with a sufficiently small threshold.¶
A malicious adversary controlling the Collector and one of the Aggregators can further turn arbitrary non-heavy prefixes into heavy ones by tampering with the IDPF output at any position. While our construction ensures that the nodes evaluated at one level are children of the nodes evaluated at the previous level, this still may allow an adversary to discover individual non-heavy strings. We call this a "steering attack".¶
The only practical, general-purpose defense against steering attacks is to compose Poplar1 with some mechanism for differential privacy. It is therefore RECOMMENDED to use differential privacy for any heavy-hitter type application.¶
The arithmetic sketch described in Section 8 is used by the Aggregators to check
that the shares of the vector obtained by evaluating a Client's IDPF at a
sequence of candidate prefixes has at most one non-zero value, and that the
non-zero value is 1
. Depending on how the values are used, the arithmetic sketch
on its own may not be sufficient for robustness of the application. In
particular, a malicious Client may attempt to influence the computation by
choosing an IDPF that evaluates to 1
at more than one node at a given
level of the tree.¶
This issue can be mitigated by using an IDPF that is extractable as defined in Appendix D of [BBCGGI21]. Extractability ensures that, for a particular level of the tree, it is infeasible for an attacker to control values of the IDPF such that it takes on chosen non-zero values at more than one node. (It can practically only achieve the zero function, a point function, or a pseudorandom function.)¶
The IDPF specified in Section 8.1 only guarantees extractability at the last level of the tree. (This is by virtue of using a larger field for the leaves than for inner nodes and using an XOF to derive leaves that is safe to model as a random oracle. See Section 9.6.) For intermediate levels, it is feasible for a client to produce IDPF shares with two controlled non-zero nodes.¶
This is not an issue for running heavy hitters, since (1) each node in the prefix tree is a child of a previously traversed node, (2) the arithmetic sketch would detect double voting at every level of the prefix tree, and (3) the IDPF is extractable at the last level of the tree. However, the lack of extractability at intermediate levels may result in attacks on the robustness of certain applications.¶
Thus applications SHOULD NOT use prefix counts for intermediate levels for any purpose beyond computing the prefix tree for heavy hitters.¶
In the security analyses of our protocols, XOFs (Section 6.2) are usually modeled as random oracles. XofTurboShake128 is designed to be indifferentiable from a random oracle [MRH04], making it a suitable choice for most situations.¶
The one exception is the IDPF of Section 8.3. Here, a random oracle is not
needed to prove privacy, since the analysis of [BBCGGI21], Proposition 1, only
requires a Pseudorandom Generator (PRG). As observed in [GKWY20], a PRG can be
instantiated from a correlation-robust hash function H
. Informally,
correlation robustness requires that for a random r
, H(xor(r, x))
is
computationally indistinguishable from a random function of x
. A PRG can
therefore be constructed as¶
PRG(r) = H(xor(r, 1)) || H(xor(r, 2)) || ...¶
since each individual hash function evaluation is indistinguishable from a random function.¶
XofFixedKeyAes128 in Section 6.2.2 implements a correlation-robust hash function using fixed-key AES. For security, it assumes that AES with a fixed key can be modeled as a random permutation [GKWY20]. Additionally, we use a different AES key for every client, which in the ideal cipher model leads to better concrete security [GKWWY20].¶
We note that for robustness, the analysis of [BBCGGI21] still assumes a random oracle to make the IDPF extractable. We therefore use XofTurboShake128 instead for the last level of the tree. It is important that XofTurboShake128 supports many seed lengths, in particular 16 bytes, as this is the seed size for the inner levels.¶
While XofFixedKeyAes128 has been shown to be differentiable from a random oracle [GKWWY20], there are no known attacks exploiting this difference. We also stress that even if the IDPF is not extractable, Poplar1 guarantees that every client can contribute to at most one prefix among the ones being evaluated by the helpers.¶
Prio3 and other systems built from the FLP of Section 7.3 may benefit from choosing a field size that is as small as possible. Generally speaking, a smaller field results in lower communication and storage costs. Care must be taken, however, since a smaller field also results in degraded (or even vacuous) robustness.¶
Different variants of Prio3 (Section 7) use different field sizes: Prio3Count and Prio3Sum use Field64; but Prio3SumVec, Prio3Histogram, and Prio3MultihotCountVec all use Field128, a field that is twice as large as Field64. This is due to the use of joint randomness (Section 7.1) in the latter variants. Joint randomness allows for more flexible circuit design (see Section 7.3.1.1), but opens up Prio3 to offline attacks in which the attacker searches for input shares for an invalid measurement that derive joint randomness that causes the circuit to accept. Choosing a large enough field ensures this computation is too expensive to be feasible. (See [DPRS23], Theorem 1.) Note that privacy is not susceptible to such attacks.¶
Another way to mitigate this issue (or improve robustness in general) is to
generate and verify multiple, independent proofs. (See Section 7.1.2.) For
Prio3, the PROOFS
parameter controls the number of proofs (at least one) that
are generated and verified. In general the soundness error of the FLP is given
by the following formula:¶
(circuit_soundness + flp_soundness)^PROOFS¶
where:¶
circuit_soundness
is the soundness of the validity circuit
(Section 7.3.2)¶
flp_soundness
is the base soundness of the proof system ([BBCGGI19],
Theorem 4.3)¶
For circuits involving joint randomness, we aim for the soundness error to be
close to 2^-128
in order to mitigate offline attacks. Such circuits MUST use
Field128 with at least one proof or Field64 with at least three proofs.
Depending on the circuit, Field64 with two proofs might have significantly
lower soundness than Field128 with one proof.¶
We stress that weak parameters (too small a field, too few proofs, or both) can be exploited to attack any aggregation task using those parameters. To mitigate offline attacks, it is necessary to disable all tasks that use the weak parameters.¶
Two Aggregators are required for privacy in our threat model, but some (V)DAFs, including Prio3 (Section 7), allow for any number of Aggregators, only one of which needs to be trusted in order for the computation to be private. To hedge against corruptions that happen during the course of the attack, deployments may consider involving more than two Aggregators as described for example in Section 5.7.2. Note however that some schemes are not compatible with this mode of operation, such as Poplar1.¶
Prio3 and Poplar1 are designed to resist some attacks that fall outside the main threat model for VDAFs.¶
Broadly speaking, domain separation is used to prevent cross protocol attacks, in which data from evaluation of one VDAF translates to an attack against another. For example:¶
Weak entropy sources: the VDAF algorithm ID is bound to each XOF invocation, thereby ensuring the outputs are different between VDAF invocations, even if the underlying randomness is the same. For example, two different instances of Prio3 would compute different measurement shares.¶
Weak parameters: Prio3 variants that require joint randomness are subject to offline attacks against robustness. These attacks are feasible if the field size or number of proofs is sufficiently small. (See Section 9.7.) The joint randomness derivation is bound to both the field (via the algorithm ID) and the number of proofs, thereby ensuring that joint randomness derived for weak parameters is not reused for stronger parameters. In addition, the joint randomness is bound to the application context, meaning any work the attacker does to attack some application is not useful for other applications that use the same parameters.¶
There are also some important limitations to be aware of. For example, Prio3
provides domain separation between families of circuits, but does not provide
domain separation between instances of a circuit. Concretely, it is possible
for Aggregators to accept a report for Prio3SumVec from a Client who disagrees
with them on the value of bits
and length
(so long as the encoded
measurement is the same size). This is because there is no
binding of the circuit parameters to the computation.¶
Implementations of VDAFs should incorporate defenses against side-channel attacks. For side-channel attacks against the privacy security goal, the relevant threat model includes an attacker that may control the Collector, a subset of Clients, and a subset of Aggregators, and monitor side-channel signals from the honest Clients and Aggregators. Side-channel attacks by third parties may indirectly target robustness by trying to leak the Aggregators' verification key. Thus, implementations of Clients and Aggregators should treat measurements, input shares, output shares, and the verification key as secret, and avoid leaking those secret values or any intermediate computations that depend on them.¶
For example, the following routines should all be implemented in a side-channel resistant manner.¶
IANA is requested to make one new registry:¶
DAF and VDAF Identifiers¶
This registry should be created under the heading "Verifiable Distributed Aggregation Functions (VDAF)", and administered under the Specification Required policy [RFC8126].¶
The "VDAF Identifiers" registry lists identifiers for Distributed Aggregation
Functions (DAFs) and Verifiable Distributed Aggregation Functions (VDAFs). These
identifiers are four-byte values, so the minimum possible value is 0x00000000
and the maximum possible value is 0xffffffff
.¶
Template:¶
Value: The four-byte identifier for the DAF or VDAF¶
Scheme: The name of the DAF or VDAF¶
Type: Either "DAF" for a Distributed Aggregation Function or "VDAF" for a Verifiable Distributed Aggregation Function¶
Reference: Where the algorithm is defined¶
The initial contents of the registry are as follows:¶
Value | Scheme | Type | Reference |
---|---|---|---|
0x00000000
|
Reserved | n/a | RFC XXXX |
0x00000001
|
Prio3Count | VDAF | Section 7.4.1 of RFC XXXX |
0x00000002
|
Prio3Sum | VDAF | Section 7.4.2 of RFC XXXX |
0x00000003
|
Prio3SumVec | VDAF | Section 7.4.3 of RFC XXXX |
0x00000004
|
Prio3Histogram | VDAF | Section 7.4.4 of RFC XXXX |
0x00000005
|
Prio3MultihotCountVec | VDAF | Section 7.4.5 of RFC XXXX |
0x00000006
|
Poplar1 | VDAF | Section 8.2 of RFC XXXX |
0xFFFF0000 to 0xFFFFFFFF
|
Reserved for Private Use | n/a | n/a |
(RFC EDITOR: Please replace "RFC XXXX" above with the RFC number assigned to this document.)¶
VDAF identifiers are used for domain separation, as described in Section 6.2.3. Domain separation guards against cross protocol attacks and certain failures of entropy sources. See Section 9.9.¶
The benefits of domain separation are undermined if different VDAFs are used with the same VDAF Identifier. The "Reserved for Private Use" code points should thus be used judiciously, because they provide no defense against such collisions. Applications SHOULD prefer the use of registered code points.¶
This section defines gadgets used to specify variants of Prio3 defined in Section 7.4 and to construct FLPs as defined in Section 7.3.¶
The multiplication gadget takes in a pair of inputs and multiplies them
together. The degree of this circuit is 2
.¶
class Mul(Gadget[F]): ARITY = 2 DEGREE = 2 def eval(self, _field: type[F], inp: list[F]) -> F: return inp[0] * inp[1] def eval_poly(self, field: type[F], inp_poly: list[list[F]]) -> list[F]: return poly_mul(field, inp_poly[0], inp_poly[1])¶
The polynomial-evaluation gadget takes in a single input x
and returns
p(x)
, where p
is a polynomial specified by the user. Its degree is the same
as p
.¶
class PolyEval(Gadget[F]): ARITY = 1 p: list[int] # polynomial coefficients def __init__(self, p: list[int]): """ Instantiate this gadget with the given polynomial. """ # Strip leading zeros. for i in reversed(range(len(p))): if p[i] != 0: p = p[:i+1] break if len(p) < 1: raise ValueError('invalid polynomial: zero length') self.p = p self.DEGREE = len(p) - 1 def eval(self, field: type[F], inp: list[F]) -> F: p = [field(coeff) for coeff in self.p] return poly_eval(field, p, inp[0]) def eval_poly(self, field: type[F], inp_poly: list[list[F]]) -> list[F]: p = [field(coeff) for coeff in self.p] out = [field(0)] * (self.DEGREE * len(inp_poly[0])) out[0] = p[0] x = inp_poly[0] for i in range(1, len(p)): for j in range(len(x)): out[j] += p[i] * x[j] x = poly_mul(field, x, inp_poly[0]) return poly_strip(field, out)¶
The parallel-sum gadget applies a subcircuit to multiple inputs in parallel,
then returns the sum of the results. The arity of the gadget is equal to count
times the arity of the subcircuit, where count
denotes the number of times the
subcircuit is called. The degree of the gadget is equal to the degree of the
subcircuit.¶
class ParallelSum(Gadget[F]): subcircuit: Gadget[F] count: int def __init__(self, subcircuit: Gadget[F], count: int): self.subcircuit = subcircuit self.count = count self.ARITY = subcircuit.ARITY * count self.DEGREE = subcircuit.DEGREE def eval(self, field: type[F], inp: list[F]) -> F: out = field(0) for i in range(self.count): start_index = i * self.subcircuit.ARITY end_index = (i + 1) * self.subcircuit.ARITY out += self.subcircuit.eval( field, inp[start_index:end_index], ) return out def eval_poly(self, field: type[F], inp_poly: list[list[F]]) -> list[F]: output_poly_length = self.DEGREE * (len(inp_poly[0]) - 1) + 1 out_sum = [field(0) for _ in range(output_poly_length)] for i in range(self.count): start_index = i * self.subcircuit.ARITY end_index = (i + 1) * self.subcircuit.ARITY out_current = self.subcircuit.eval_poly( field, inp_poly[start_index:end_index] ) for j in range(output_poly_length): out_sum[j] += out_current[j] return poly_strip(field, out_sum)¶
This section specifies two "shim" gadgets, one for generating an FLP as specified in Section 7.3.3 and another for querying an FLP as specified in Section 7.3.4.¶
class ProveGadget(Gadget[F]): """ Gadget wrapper that records the input wires for each evaluation. """ def __init__(self, field: type[F], wire_seeds: list[F], g: Gadget[F], g_calls: int): p = next_power_of_2(1 + g_calls) self.inner = g self.ARITY = g.ARITY self.DEGREE = g.DEGREE self.wires = [] self.k = 0 # evaluation counter for s in wire_seeds: wire = field.zeros(p) wire[0] = s # set the wire seed self.wires.append(wire) def eval(self, field: type[F], inp: list[F]) -> F: self.k += 1 for j in range(len(inp)): self.wires[j][self.k] = inp[j] return self.inner.eval(field, inp) def eval_poly(self, field: type[F], inp_poly: list[list[F]]) -> list[F]: return self.inner.eval_poly(field, inp_poly) @classmethod def wrap(cls, valid: Valid[Measurement, AggResult, F], prove_rand: list[F], ) -> Valid[Measurement, AggResult, F]: """ Make a copy of `valid` with each gadget wrapped for recording the wire inputs. `prove_rand` is used to produce the wire seeds for each gadget. """ wrapped_gadgets: list[Gadget[F]] = [] for (g, g_calls) in zip(valid.GADGETS, valid.GADGET_CALLS): (wire_seeds, prove_rand) = front(g.ARITY, prove_rand) wrapped = cls(valid.field, wire_seeds, g, g_calls) wrapped_gadgets.append(wrapped) wrapped_valid = deepcopy(valid) wrapped_valid.GADGETS = wrapped_gadgets return wrapped_valid class QueryGadget(Gadget[F]): """ Gadget wrapper that records the input wires for each evaluation. Rather than evaluate the circuit, use the provided gadget polynomial to produce the output. """ def __init__( self, field: type[F], wire_seeds: list[F], gadget_poly: list[F], g: Gadget[F], g_calls: int): p = next_power_of_2(1 + g_calls) self.alpha = field.gen() ** (field.GEN_ORDER // p) self.poly = gadget_poly self.ARITY = g.ARITY self.DEGREE = g.DEGREE self.wires = [] self.k = 0 for s in wire_seeds: wire = field.zeros(p) wire[0] = s # set the wire seed self.wires.append(wire) def eval(self, field: type[F], inp: list[F]) -> F: self.k += 1 for j in range(len(inp)): self.wires[j][self.k] = inp[j] return poly_eval(field, self.poly, self.alpha ** self.k) @classmethod def wrap(cls, valid: Valid[Measurement, AggResult, F], proof: list[F]) -> Valid[Measurement, AggResult, F]: wrapped_gadgets: list[Gadget[F]] = [] for (g, g_calls) in zip(valid.GADGETS, valid.GADGET_CALLS): p = next_power_of_2(1 + g_calls) gadget_poly_len = g.DEGREE * (p - 1) + 1 (wire_seeds, proof) = front(g.ARITY, proof) (gadget_poly, proof) = front(gadget_poly_len, proof) wrapped = cls(valid.field, wire_seeds, gadget_poly, g, g_calls) wrapped_gadgets.append(wrapped) wrapped_valid = deepcopy(valid) wrapped_valid.GADGETS = wrapped_gadgets return wrapped_valid¶
This section lists the classes used to define each Aggregator's state during VDAF preparation (Section 5.7).¶
class State: pass class Start(State): pass class Continued(State, Generic[PrepState]): def __init__(self, prep_state: PrepState, prep_round: int): self.prep_state = prep_state self.prep_round = prep_round def __eq__(self, other: object) -> bool: return isinstance(other, Continued) and \ self.prep_state == other.prep_state and \ self.prep_round == other.prep_round class Finished(State, Generic[OutShare]): def __init__(self, out_share: OutShare): self.out_share = out_share def __eq__(self, other: object) -> bool: return isinstance(other, Finished) and \ self.out_share == other.out_share class Rejected(State): pass¶
Test vectors for Prio3 (Section 7) and Poplar1 (Section 8) are available at
[TestVectors]. The test vector directory, test_vec/vdaf
, contains a set of
JSON files. Each file contains a test vector for an instance of class Vdaf
as
defined in Section 5. A test vector covers sharding, preparation, aggregation,
and unsharding of a batch of several measurements. The test vector schema is
defined below.¶
ctx
:The application context string encoded in hexadecimal.¶
verify_key
:The verification key encoded in hexadecimal.¶
agg_param
:The aggregation parameter encoded in hexadecimal.¶
prep
:A list of objects with the following schema:¶
measurement
:The measurement of type Measurement
defined by the VDAF.¶
nonce
:The nonce encoded in hexadecimal.¶
rand
:The sharding randomness encoded in hexadecimal.¶
public_share
:The expected public share encoded in hexadecimal.¶
input_shares
:The expected list of input shares, each encoded in hexadecimal.¶
prep_shares
:The expected list of prep shares generated by each Aggregator at each round of preparation, encoded in hexadecimal.¶
prep_messages
:The expected list of prep messages for each round of preparation, encoded in hexadecimal.¶
out_shares
:The expected list of output shares, encoded in hexadecimal.¶
agg_shares
:The expected aggregate shares encoded in hexadecimal.¶
agg_result
:The expected aggregate result of type AggResult
defined by the VDAF.¶
The schema also includes whatever parameters are required to instantiate the VDAF. These are listed in the subsections below.¶
shares
:The number of shares, an integer.¶
The impetus of this work is the success of recent deployments of predecessors of Prio3. These include the Mozilla Origin Telemetry project [OriginTelemetry] and the Exposure Notification Private Analytics system [ENPA] developed jointly by ISRG, Google, Apple, and others. Together these systems have aggregated data from hundreds of millions of users.¶
As the name implies, Prio3 is a descendant of the original Prio construction [CGB17]. A second iteration was deployed in the [ENPA] system, and like the VDAF described here, the ENPA system was built from techniques introduced in [BBCGGI19] that significantly improve communication cost. That system was specialized for a particular aggregation function; the goal of Prio3 is to provide the same level of generality as the original construction.¶
The security considerations in Section 9 are based largely on the security analysis of [DPRS23]. Thanks to Hannah Davis and Mike Rosulek, who lent their time to developing definitions and security proofs.¶
Thanks to Junye Chen, Henry Corrigan-Gibbs, Armando Faz-Hernández, Simon Friedberger, Tim Geoghegan, Albert Liu, Brandon Pitman, Mariana Raykova, Michael Rosenberg, Jacob Rothstein, Shan Wang, Xiao Wang, Bas Westerbaan, and Christopher Wood for useful feedback on and contributions to the spec.¶