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Efficient Consistency Proofs for Generalized Queries on a Committed Database

Explore achieving short certificates and proofs for queries on committed databases, ensuring consistency and security against cheating parties. Learn about innovative protocols, contributions, and applications in this comprehensive study.

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Efficient Consistency Proofs for Generalized Queries on a Committed Database

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  1. Efficient Consistency Proofs for Generalized Queries on a Committed Database R. Ostrovsky C. Rackoff A. Smith UCLA Toronto U. MIT July 12, 2004 http://www.cs.ucla.edu/~rafail

  2. Main goal • Potentially cheating party publishes a short certificate to a “database” which “commits” it to the entire database • Answers to any complex query can be shown (with a very short proof) to be consistent with the certificate • No poly-time adversary can cheat and come up with a certificate and two different answers to the same query • Main challenge – achieve short certificate and short proofs for general queries

  3. History • Commitment to Sets of Values • [Buldas, Laud, Lipmaa] • [Kilian] • [Micali and Rabin] • Protocols with Trusted Committer – Authenticated Data-Structures • [Naor, Nissim] • [Goodrich, Tamassia, Tiandopoulus, Cohen], • many others • Zero-Knowledge Sets • [Micali, Rabin Kilian]

  4. Our Contributions (1) • Def of Consistent Query Protocols (CQP): short certificate that “binds” general data-structures together with short proof of consistency • CQP for Orthogonal Range queries

  5. Our contributions (cont) • For orthogonal range queries: • Each entry: (key1,…keyd, value) • Query: d ranges, each range [x1,x2] • d dimensions • K is a security parameter • Proof size: O(k(m+1) logdN) • We show how to modify Bentley’s data structure. (authenticated data-structures are not sufficient)

  6. Our contributions (cont) • General transformation: we show how to modify any consistent query protocol to have the same property as ZK-sets. That is, not to reveal DB size using O(poly(k)) overhead based on general assumptions. • We show construction based on explicit-hash Merkle trees with better constants.

  7. The rest of the talk… • Machinery needed. • Some of the ideas in our constructions.

  8. Motivation – Commitment Protocols • Two player game: Committer and Receiver. • Commitment stage: “storing” some hidden value. • De-commit stage: “opening” this value. • Two properties: binding property and privacy property.

  9. An example of a commitment protocol • Alice has a hidden bit b. • Alice picks a 1-way permutation f:nn, a random n-bit x, r and sends to Bob • f(x), [(x*r) mod 2] xor b • If f is verifiable 1-way permutation, this is both binding and secure. • To open, Alice sends x to Bob.

  10. Multiple commitments • What if Alice wants to commit • b1,…,bn • One way to do it is to repeat the protocol above, and commit each bit separately. • How can we do it more efficiently?

  11. A faster way to do it – Merkle trees • Assume h: 2kk is a collision-resistant hash function such that no poly-time adversary can find a collision. • Group N bits that we wish to commit into groups of size 2k each, apply h, Now, we have N/2 bits. Repeat until get to k bit. • Commit (using basic scheme) the last k bits. • Merkle: this is secure, since otherwise can find a collision.

  12. Commitment of a set • Committing to a set of integers. • The naïve approach: commit each integer separately using basic scheme • Easy on yes answers • Hard on “no” answers

  13. Do Merkle trees work? • Not as is. • Yes answers are fast • No answers are slow– have to go over all the leaves • [BLL][K][MR] gave a faster solution (for no asnwers) for a set based on Merkle trees. (If the set has total order the solution also works for intervals)

  14. The basic idea of [BLL][K][MR]:Merkle interval tree • Sort the keys • Each internal node contains: • Left sub tree interval • Right sub tree interval • MD5 of its children values • To show that the item is present, show the path to the root, with all siblings along the path. • To show that the item is NOT in the DB, show the path until intervals EXCLUDES the item.

  15. Orthogonal range queries • What if we wish to commit to more general data-objects, such as relational database? Example: DB of “employee name”, “age”, “salary”. • We wish to support range-queries of the form “find all employees between age 30-40 and between salary x and y”. • What does Consistent range-query mean here? • In this talk: we’ll limit to 2-d range queries, though our solution generalizes.

  16. 2-D range queries: the data-structure • DB: (xkey,ykey, value) • Query: find all entries in DB in the rectangle [x1,x2][y1,y2] • Modification to Bentley’s 2-dim range query • Make Merkle-Interval tree for X-coordinate • For each internal node (corresponding to X-interval) store inside the node the root of “secondary” Merkle Interval tree for Y coordinates in that X-range. (each y point is stored log N times)

  17. 2-D range queries: searching for range • Search primary tree and check for consistency • Search a secondary tree and check for consistency • For each entry that is retrieved, check that it is valid in ALL secondary trees which are on the path to the root in the primary tree. (Takes O(log2N) steps). • Easy to generalize to d-dimensions • Proof: if Adv can chat on any range  can find collisions.

  18. Extending idea to Zero-Knowledge Sets • Previous scheme works for 2-dimensional ranges • [KMR] show how to extends to ZK-sets (i.e. Not to reveal N) using DDH assumption. • We show how to extend this idea to Zero-Knowledge Sets under general assumptions using [Barak-Golreich] universal arguments: • Commit to a root • Give a commitment of CQP • Give a [BG] universal argument of supper-poly bound on N of consistency.

  19. Conclusions • Consistent query protocols (CQP) are generalizations of: • Zero-knowledge sets • Commitment schemes (for large datasets) • Authenticated Data structures • CQP be achieved under general assumptions. • For special cases (such as low-dimensional range-queries) we show implementations that do not require PCP, and are efficient. (O(log N) away from best know non-private bound)

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