Damien Vergnaud scite author profile

In 1998, Blaze, Bleumer, and Strauss proposed a cryptographic primitive called proxy re-encryption, in which a proxy transforms-without seeing the corresponding plaintext-a ciphertext computed under Alice's public key into one that can be opened using Bob's secret key. Recently, an appropriate definition of chosen-ciphertext security and a construction fitting this model were put forth by Canetti and Hohenberger. Their system is bidirectional : the information released to divert ciphertexts from Alice to Bob can also be used to translate ciphertexts in the opposite direction. In this paper, we present the first construction of unidirectional proxy re-encryption scheme with chosenciphertext security in the standard model (i.e. without relying on the random oracle idealization), which solves a problem left open at CCS'07. Our construction is efficient and requires a reasonable complexity assumption in bilinear map groups. Like the Canetti-Hohenberger scheme, it ensures security according to a relaxed definition of chosen-ciphertext introduced by Canetti, Krawczyk and Nielsen.

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Unidirectional Chosen-Ciphertext Secure Proxy Re-Encryption

Libert

Vergnaud

2011

IEEE Trans. Inform. Theory

157

139

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In 1998, Blaze, Bleumer and Strauss introduced a cryptographic primitive called proxy re-encryption (PRE) in which a proxy can transform -without seeing the plaintext -a ciphertext encrypted under one key into an encryption of the same plaintext under another key. The concept has recently drawn renewed interest. Notably, Canetti and Hohenberger showed how to properly define (and realize) chosen-ciphertext security for the primitive. Their system is bidirectional as the translation key allows converting ciphertexts in both directions. This paper presents the first unidirectional proxy re-encryption schemes with chosen-ciphertext security in the standard model (i.e. without the random oracle idealization). The first system provably fits a unidirectional extension of the Canetti-Hohenberger security model. As a second contribution, the paper considers a more realistic adversarial model where attackers may choose dishonest users' keys on their own. It is shown how to modify the first scheme to achieve security in the latter scenario. At a moderate expense, the resulting system provides additional useful properties such as non-interactive temporary delegations. Both constructions are efficient and rely on mild complexity assumptions in bilinear groups. Like the Canetti-Hohenberger scheme, they meet a relaxed flavor of chosen-ciphertext security introduced by Canetti, Krawczyk and Nielsen. This is the full version of a paper with the same title presented in Public Key Cryptography 2008 [37].

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Lossy Encryption: Constructions from General Assumptions and Efficient Selective Opening Chosen Ciphertext Security

et al. 2011

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Lossy encryption was originally studied as a means of achieving efficient and composable oblivious transfer. Bellare, Hofheinz and Yilek showed that lossy encryption is also selective opening secure. We present new and general constructions of lossy encryption schemes and of cryptosystems secure against selective opening adversaries.We show that every re-randomizable encryption scheme gives rise to efficient encryptions secure against a selective opening adversary. We show that statistically-hiding 2-round Oblivious Transfer implies Lossy Encryption and so do smooth hash proof systems. This shows that private information retrieval and homomorphic encryption both imply Lossy Encryption, and thus Selective Opening Secure Public Key Encryption.Applying our constructions to well-known cryptosystems, we obtain selective opening secure commitments and encryptions from the Decisional Diffie-Hellman, Decisional Composite Residuosity and Quadratic Residuosity assumptions.In an indistinguishability-based model of chosen-ciphertext selective opening security, we obtain secure schemes featuring short ciphertexts under standard number theoretic assumptions. In a simulation-based definition of chosen-ciphertext selective opening security, we also handle non-adaptive adversaries by adapting the Naor-Yung paradigm and using the perfect zeroknowledge proofs of Groth, Ostrovsky and Sahai.

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Damien Vergnaud

Unidirectional Chosen-Ciphertext Secure Proxy Re-encryption

Unidirectional Chosen-Ciphertext Secure Proxy Re-Encryption

Lossy Encryption: Constructions from General Assumptions and Efficient Selective Opening Chosen Ciphertext Security

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