International audienceIn typical applications of homomorphic encryption, the first step consists for Alice to encrypt some plaintext m under Bob’s public key pk and to send the ciphertext c = HEpk(m) to some third-party evaluator Charlie. This paper specifically considers that first step, i.e. the problem of transmitting c as efficiently as possible from Alice to Charlie. As previously noted, a form of compression is achieved using hybrid encryption. Given a symmetric encryption scheme E, Alice picks a random key k and sends a much smaller ciphertext c′ = (HEpk(k), Ek(m)) that Charlie decompresses homomorphically into the original c using a decryption circuit CE−1 .In this paper, we revisit that paradigm in light of its concrete implemen- tation constraints; in particular E is chosen to be an additive IV-based stream cipher. We investigate the performances offered in this context by Trivium, which belongs to the eSTREAM portfolio, and we also pro- pose a variant with 128-bit security: Kreyvium. We show that Trivium, whose security has been firmly established for over a decade, and the new variant Kreyvium have an excellent performance

Canteaut, Anne

Carpov, Sergiu

Fontaine, Caroline

Lepoint, Tancrède

Naya-Plasencia, María

Paillier, Pascal

Sirdey, Renaud

HAL-Université de Bretagne Occidentale

Stream ciphers: A Practical Solution for Efficient Homomorphic-Ciphertext Compression

INRIA a CCSD electronic archive server

International audienceIn typical applications of homomorphic encryption, the rststep consists for Alice to encrypt some plaintext m under Bob's publickey pk and to send the ciphertext c = HEpk(m) to some third-partyevaluator Charlie. This paper specically considers that rst step, i.e.the problem of transmitting c as eciently as possible from Alice toCharlie. As previously noted, a form of compression is achieved usinghybrid encryption. Given a symmetric encryption scheme E, Alice picks arandom key k and sends a much smaller ciphertext c0 = (HEpk(k); Ek(m))that Charlie decompresses homomorphically into the original c using adecryption circuit C(E^{-1}).In this paper, we revisit that paradigm in light of its concrete implementationconstraints; in particular E is chosen to be an additive IV-basedstream cipher. We investigate the performances oered in this contextby Trivium, which belongs to the eSTREAM portfolio, and we also proposea variant with 128-bit security: Kreyvium. We show that Trivium,whose security has been rmly established for over a decade, and thenew variant Kreyvium have an excellent performance

Stream Ciphers: A Practical Solution for Efficient Homomorphic-Ciphertext Compression

HAL Id: hal-01401328https://hal.inria.fr/hal-01401328Submitted on 23 Nov 2016HAL is a multi-disciplinary open accessarchive for the deposit and dissemination of sci-entific research documents, whether they are pub-lished or not. The documents may come fromteaching and research institutions in France orabroad, or from public or private research centers.L’archive ouverte pluridisciplinaire HAL, estdestinée au dépôt et à la diffusion de documentsscientifiques de niveau recherche, publiés ou non,émanant des établissements d’enseignement et derecherche français ou étrangers, des laboratoirespublics ou privés.Stream Ciphers: A Practical Solution for EfficientHomomorphic-Ciphertext CompressionAnne Canteaut, Sergiu Carpov, Caroline Fontaine, Tancrède Lepoint, MaríaNaya-Plasencia, Pascal Paillier, Renaud SirdeyTo cite this version:Anne Canteaut, Sergiu Carpov, Caroline Fontaine, Tancrède Lepoint, María Naya-Plasencia, et al..Stream Ciphers: A Practical Solution for Efficient Homomorphic-Ciphertext Compression. CryptoAc-tion Symposium 2016, Apr 2016, Budapest, Hungary. ￿hal-01401328￿Stream ciphers: A Practical Solution for EfficientHomomorphic-Ciphertext CompressionAnne Canteaut, Sergiu Carpov, Caroline Fontaine, Tancrède Lepoint,María Naya-Plasencia, Pascal Paillier, Renaud SirdeyInria Paris, CEA LIST, CNRS, Telecom Bretagne and UEB, CryptoExperts (France)CryptoAction Symposium, Budapest, April 2016Motivation1Homomorphic encryptionHEpk(f(x)) = HE.Evalf(HEpk(x))Typical ciphertext expansion: 200 kBytes for encrypting a single bit2Optimizing communication using symmetric encryption [Naehrig et al. 11]k HEpk(·) HEpk(k)m EEk(m) Ek(m)no ciphertext expansionC HEpk(m)C = HE.EvalE−1Question: What kind of symmetric encryption is the most appropriate?3Prior HE-friendly ciphersAim:Minimize the multiplicative depth of the decryption function.Concrete proposals:• Optimized implementations of AES [Gentry Halevi Smart 12][Cheon et al. 13][Döroz Hu Sunar 14]• Lightweight block ciphers: SIMON [Lepoint Naehrig 14], PRINCE [Doröz et al.14]• Dedicated block cipher: Low-MC [Albrecht et al. 15]4Outline1. Revisiting the whole encryption scheme2. Trivium and Kreyvium in the HE setting3. Experimental results5Ciphertext decompression with IV-based encryptionk HEpk(·) HEpk(k)IVm EEk(m)key setupIVEk(m)offline phaseonline phase HEpk(m)offlineonline→ Reduce the online phase to a minimum.6With an additive stream cipherkIVHEpk(·)ZGx1 xtF F F · · · Fz1 z2 z3 · · · ztkeystream =offlineonlinem ⊕ m⊕ keystreamHEpk(k)IVGx1 xtCF CF CF · · · CFHEpk(keystream)C⊕ HEpk(m)→ Minimize the multiplicative depth of F .7Instantiation with a counterExpansion function G:G(IV ) = (IV, IV  1, IV  2, . . . , IV  (t− 1))Why not use for F a block cipher?security limited to 2n/2 where n is the block size.→ strong limitation for lightweight ciphers with n = 64 or 32.8Low-depth keystream geneartorinternal state			???-? ?k xkeystreamΦfInit• We need a transition function Φ with a low multiplicative depth.• No strong limitation of the size of the internal state.9Trivium and Kreyviumtwo low-depth stream ciphers10Trivium [De Cannière Preneel 08]recommended by the eSTREAM project• transition function with degree 2• key size = 80 bits• IV size = 80 bits• initialization = 1152 blank rounds11Trivium [De Cannière Preneel 08]12Multiplicative depth of TriviumThe keystream length which can be produced with a circuit of depth d, d ≥ 4, is282×d3 +81 if d ≡ 0 mod 3160 if d ≡ 1 mod 3269 if d ≡ 2 mod 3• At depth 12, 57 bits• At depth 13, 136 bits13Kreyvium, a 128-bit version of Triviumkey size = IV size = 128 bitsIncreasing the size of the internal state.• no cost if the additionnal part is updated linearly• better resistance to TMDTO attacks and to algebraic attacks if the additionnal partcontains some secret material→ the 128-bit key and the 128-bit IV are added to the internal stateSize of the internal state = 544 bits (416 are unknown)14Kreyvium0243 288286 28769 91 929366171162 177175 176264015Multiplicative depth of KreyviumThe keystream length which can be produced with a circuit of depth d, d ≥ 4, is282×d3 +70 if d ≡ 0 mod 3149 if d ≡ 1 mod 3258 if d ≡ 2 mod 3→ 11 bits less than with Trivium• At depth 12, 46 bits• At depth 13, 125 bits16Some security argumentsInternal state collision:the number of keystream bits generated from the same key/IV pair must be less than 2144.Algebraic attacks [Maximov Biryukov 07]:every relation corresponding to a keystream bit introduces a new unknown in the system.Cube testers [Dinur Shamir 09][Aumasson et al. 09][Fouque Vannet 13]:two additional XORs per round → better mixing of the variablesConditional differential cryptanalysis [Knellwolf et al. 11]even in the weak-key setting, 64 bits can never be set to 017Experimental results18Using HElib (on one core of a server with 4 x AMD Opteron 6172 processors)security level N used depth #slots latency throughput(sec.) (bits/min)Trivium-13 80 136 13 600 3650 134120 720 11380 516Kreyvium-13 128 125 13 682 3987 127220 480 12451 287LowMC-128 ? ≤ 118 256 13 682 3369 310920 480 9977 73919Using the Fan-Vercauteren scheme on a 48-core serversecurity level N used depth throughput (bits/min) Speed gain1 core 48 coresTrivium-13 80 136 13 9.2 240 × 26.220 3.4 106 × 31.0Kreyvium-13 128 125 13 5.7 151 × 26.520 2.2 77 × 34.0LowMC-128 ? ≤ 118 256 14 10.0 90 × 9.021 4.6 47 × 10.220Conclusions• IV-based stream ciphers are the most appropriate ciphers.• Good performances can be obtained with firmly-established symmetric ciphers.Open question.How many multiplicative levels are necessary to achieve a reasonable security level?→ (impractical) approach based on discrete-log achieving a multiplicative depthof (dlog κe+ 1) for κ-bit security.21

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Stream ciphers: A Practical Solution for Efficient Homomorphic-Ciphertext Compression

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