Breaking and Fixing of an Identity Based Multi-Signcryption Scheme

Signcryption is a cryptographic primitive that provides authentication and confidentiality simultaneously in a single logical step. It is often required that multiple senders have to signcrypt a single message to a certain receiver. Obviously, it is inefficient to signcrypt the messages separately. An efficient alternative is to go for multi-signcryption. The concept of multi-signcryption is similar to that of multi-signatures with the added property - confidentiality. Recently, Jianhong et al. proposed an identity based multi-signcryption scheme. They claimed that their scheme is secure against adaptive chosen ciphertext attack and it is existentially unforgeable. In this paper, we show that their scheme is not secure against chosen plaintext attack and is existentially forgeable, we also provide a fix for the scheme and prove formally that the improved scheme is secure against both adaptive chosen ciphertext attack and existential forgery

Critical Perspectives on Provable Security: Fifteen Years of Another Look Papers

We give an overview of our critiques of “proofs” of security and a guide to our papers on the subject that have appeared over the past decade and a half. We also provide numerous additional examples and a few updates and errata

Preuves mécanisées de protocoles cryptographiques et leur lien avec des implémentations vérifiées

Cryptographic protocols are one of the foundations for the trust people put in computer systems nowadays, be it online banking, any web or cloud services, or secure messaging. One of the best theoretical assurances for cryptographic protocol security is reached through proofs in the computational model. Writing such proofs is prone to subtle errors that can lead to invalidation of the security guarantees and, thus, to undesired security breaches. Proof assistants strive to improve this situation, have got traction, and have increasingly been used to analyse important real-world protocols and to inform their development. Writing proofs using such assistants requires a substantial amount of work. It is an ongoing endeavour to extend their scope through, for example, more automation and detailed modelling of cryptographic building blocks. This thesis shows on the example of the CryptoVerif proof assistant and two case studies, that mechanized cryptographic proofs are practicable and useful in analysing and designing complex real-world protocols.The first case study is on the free and open source Virtual Private Network (VPN) protocol WireGuard that has recently found its way into the Linux kernel. We contribute proofs for several properties that are typical for secure channel protocols. Furthermore, we extend CryptoVerif with a model of unprecedented detail of the popular Diffie-Hellman group Curve25519 used in WireGuard.The second case study is on the new Internet standard Hybrid Public Key Encryption (HPKE), that has already been picked up for use in a privacy-enhancing extension of the TLS protocol (ECH), and in the Messaging Layer Security secure group messaging protocol. We accompanied the development of this standard from its early stages with comprehensive formal cryptographic analysis. We provided constructive feedback that led to significant improvements in its cryptographic design. Eventually, we became an official co-author. We conduct a detailed cryptographic analysis of one of HPKE's modes, published at Eurocrypt 2021, an encouraging step forward to make mechanized cryptographic proofs more accessible to the broader cryptographic community.The third contribution of this thesis is of methodological nature. For practical purposes, security of implementations of cryptographic protocols is crucial. However, there is frequently a gap between a cryptographic security analysis and an implementation that have both been based on a protocol specification: no formal guarantee exists that the two interpretations of the specification match, and thus, it is unclear if the executable implementation has the guarantees proved by the cryptographic analysis. In this thesis, we close this gap for proofs written in CryptoVerif and implementations written in F*. We develop cv2fstar, a compiler from CryptoVerif models to executable F* specifications using the HACL* verified cryptographic library as backend. cv2fstar translates non-cryptographic assumptions about, e.g., message formats, from the CryptoVerif model to F* lemmas. This allows to prove these assumptions for the specific implementation, further deepening the formal link between the two analysis frameworks. We showcase cv2fstar on the example of the Needham-Schroeder-Lowe protocol. cv2fstar connects CryptoVerif to the large F* ecosystem, eventually allowing to formally guarantee cryptographic properties on verified, efficient low-level code.Les protocoles cryptographiques sont l'un des fondements de la confiance que la société accorde aujourd'hui aux systèmes informatiques, qu'il s'agisse de la banque en ligne, d'un service web, ou de la messagerie sécurisée. Une façon d'obtenir des garanties théoriques fortes sur la sécurité des protocoles cryptographiques est de les prouver dans le modèle calculatoire. L'écriture de ces preuves est délicate : des erreurs subtiles peuvent entraîner l'invalidation des garanties de sécurité et, par conséquent, des failles de sécurité. Les assistants de preuve visent à améliorer cette situation. Ils ont gagné en popularité et ont été de plus en plus utilisés pour analyser des protocoles importants du monde réel, et pour contribuer à leur développement. L'écriture de preuves à l'aide de tels assistants nécessite une quantité substantielle de travail. Un effort continu est nécessaire pour étendre leur champ d'application, par exemple, par une automatisation plus poussée et une modélisation plus détaillée des primitives cryptographiques. Cette thèse montre sur l'exemple de l'assistant de preuve CryptoVerif et deux études de cas, que les preuves cryptographiques mécanisées sont praticables et utiles pour analyser et concevoir des protocoles complexes du monde réel. La première étude de cas porte sur le protocole de réseau virtuel privé (VPN) libre et open source WireGuard qui a récemment été intégré au noyau Linux. Nous contribuons des preuves pour plusieurs propriétés typiques des protocoles de canaux sécurisés. En outre, nous étendons CryptoVerif avec un modèle d'un niveau de détail sans précédent du groupe Diffie-Hellman populaire Curve25519 utilisé dans WireGuard. La deuxième étude de cas porte sur la nouvelle norme Internet Hybrid Public Key Encryption (HPKE), qui est déjà utilisée dans une extension du protocole TLS destinée à améliorer la protection de la vie privée (ECH), et dans Messaging Layer Security, un protocole de messagerie de groupe sécurisée. Nous avons accompagné le développement de cette norme dès les premiers stades avec une analyse cryptographique formelle. Nous avons fourni des commentaires constructifs ce qui a conduit à des améliorations significatives dans sa conception cryptographique. Finalement, nous sommes devenus un co-auteur officiel. Nous effectuons une analyse cryptographique détaillée de l'un des modes de HPKE, publiée à Eurocrypt 2021, un pas encourageant pour rendre les preuves cryptographiques mécanisées plus accessibles à la communauté des cryptographes. La troisième contribution de cette thèse est de nature méthodologique. Pour des utilisations pratiques, la sécurité des implémentations de protocoles cryptographiques est cruciale. Cependant, il y a souvent un écart entre l'analyse de la sécurité cryptographique et l'implémentation, tous les deux basées sur la même spécification d'un protocole : il n'existe pas de garantie formelle que les deux interprétations de la spécification correspondent, et donc, il n'est pas clair si l'implémentation exécutable a les garanties prouvées par l'analyse cryptographique. Dans cette thèse, nous comblons cet écart pour les preuves écrites en CryptoVerif et les implémentations écrites en F*. Nous développons cv2fstar, un compilateur de modèles CryptoVerif vers des spécifications exécutables F* en utilisant la bibliothèque cryptographique vérifiée HACL* comme fournisseur de primitives cryptographiques. cv2fstar traduit les hypothèses non cryptographiques concernant, par exemple, les formats de messages, du modèle CryptoVerif vers des lemmes F*. Cela permet de prouver ces hypothèses pour l'implémentation spécifique, ce qui approfondit le lien formel entre les deux cadres d'analyse. Nous présentons cv2fstar sur l'exemple du protocole Needham-Schroeder-Lowe. cv2fstar connecte CryptoVerif au grand écosystème F*, permettant finalement de garantir formellement des propriétés cryptographiques sur du code de bas niveau efficace vérifié

Elliptic Curve Cryptography on Modern Processor Architectures

Abstract Elliptic Curve Cryptography (ECC) has been adopted by the US National Security Agency (NSA) in Suite "B" as part of its "Cryptographic Modernisation Program ". Additionally, it has been favoured by an entire host of mobile devices due to its superior performance characteristics. ECC is also the building block on which the exciting field of pairing/identity based cryptography is based. This widespread use means that there is potentially a lot to be gained by researching efficient implementations on modern processors such as IBM's Cell Broadband Engine and Philip's next generation smart card cores. ECC operations can be thought of as a pyramid of building blocks, from instructions on a core, modular operations on a finite field, point addition & doubling, elliptic curve scalar multiplication to application level protocols. In this thesis we examine an implementation of these components for ECC focusing on a range of optimising techniques for the Cell's SPU and the MIPS smart card. We show significant performance improvements that can be achieved through of adoption of EC

Advances in Information Security and Privacy

With the recent pandemic emergency, many people are spending their days in smart working and have increased their use of digital resources for both work and entertainment. The result is that the amount of digital information handled online is dramatically increased, and we can observe a significant increase in the number of attacks, breaches, and hacks. This Special Issue aims to establish the state of the art in protecting information by mitigating information risks. This objective is reached by presenting both surveys on specific topics and original approaches and solutions to specific problems. In total, 16 papers have been published in this Special Issue

Advances in signatures, encryption, and E-Cash from bilinear groups

Thesis (Ph. D.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 2006.Includes bibliographical references (p. 147-161).We present new formal definitions, algorithms, and motivating applications for three natural cryptographic constructions. Our constructions are based on a special type of algebraic group called bilinear groups. 1. Re-Signatures: We present the first public key signature scheme where a semi-trusted proxy, given special information, can translate Alice's signature on a message into Bob's signature on the same message. The special information, however, allows nothing else, i.e., the proxy cannot translate from Bob to Alice, nor can it sign on behalf of either Alice or Bob. We show that a path through a graph can be cheaply authenticated using this scheme, with applications to electronic passports. 2. Re-Encryption: We present the first public key cryptosystem where a semi-trusted proxy, given special information, can translate an encryption of a message under Alice's key into an encryption of the same message under Bob's key. Again, the special information allows nothing else, i.e. the proxy cannot translate from Bob to Alice, decrypt on behalf of either Alice or Bob, or learn anything else about the message. We apply this scheme to create a new mechanism for secure distributed storage.(cont.) 3. Compact; E-Cash with Tracing and Bounded-Anonymity: We present an offline e-cash system where 2 coins can be stored in O(e + k) bits and withdrawn or spent in 0(f + k) time, where k is the security parameter. The best previously known schemes required at least one of these complexities to be 0(2t . k). In our system, a user's transactions are anonymous and unlinkable, unless she performs a forbidden action, such as double-spending a coin. Performing a forbidden action reveals the identity of the user, and optionally allows to trace all of her past transactions. We provide solutions without using a trusted party. We argue why features of our system are likely to be crucial to the adoption of any e-cash system.by Susan Hohenberger.Ph.D

Searchable Encryption for Cloud and Distributed Systems

The vast development in information and communication technologies has spawned many new computing and storage architectures in the last two decades. Famous for its powerful computation ability and massive storage capacity, cloud services, including storage and computing, replace personal computers and software systems in many industrial applications. Another famous and influential computing and storage architecture is the distributed system, which refers to an array of machines or components geographically dispersed but jointly contributes to a common task, bringing premium scalability, reliability, and efficiency. Recently, the distributed cloud concept has also been proposed to benefit both cloud and distributed computing. Despite the benefits of these new technologies, data security and privacy are among the main concerns that hinder the wide adoption of these attractive architectures since data and computation are not under the control of the end-users in such systems. The traditional security mechanisms, e.g., encryption, cannot fit these new architectures since they would disable the fast access and retrieval of remote storage servers. Thus, an urgent question turns to be how to enable refined and efficient data retrieval on encrypted data among numerous records (i.e., searchable encryption) in the cloud and distributed systems, which forms the topic of this thesis. Searchable encryption technologies can be divided into Searchable Symmetric Encryption (SSE) and Public-key Encryption with Keyword Search (PEKS). The intrinsical symmetric key hinders data sharing since it is problematic and insecure to reveal one’s key to others. However, SSE outperforms PEKS due to its premium efficiency and is thus is prefered in a number of keyword search applications. Then multi-user SSE with rigorous and fine access control undoubtedly renders a satisfactory solution of both efficiency and security, which is the first problem worthy of our much attention. Second, functions and versatility play an essential role in a cloud storage application but it is still tricky to realize keyword search and deduplication in the cloud simultaneously. Large-scale data usually renders significant data redundancy and saving cloud storage resources turns to be inevitable. Existing schemes only facilitate data retrieval due to keywords but rarely consider other demands like deduplication. To be noted, trivially and hastily affiliating a separate deduplication scheme to the searchable encryption leads to disordered system architecture and security threats. Therefore, attention should be paid to versatile solutions supporting both keyword search and deduplication in the cloud. The third problem to be addressed is implementing multi-reader access for PEKS. As we know, PEKS was born to support multi-writers but enabling multi-readers in PEKS is challenging. Repeatedly encrypting the same keyword with different readers’ keys is not an elegant solution. In addition to keyword privacy, user anonymity coming with a multi-reader setting should also be formulated and preserved. Last but not least, existing schemes targeting centralized storage have not taken full advantage of distributed computation, which is considerable efficiency and fast response. Specifically, all testing tasks between searchable ciphertexts and trapdoor/token are fully undertaken by the only centralized cloud server, resulting in a busy system and slow response. With the help of distributed techniques, we may now look forward to a new turnaround, i.e., multiple servers jointly work to perform the testing with better efficiency and scalability. Then the intractable multi-writer/multi-reader mode supporting multi-keyword queries may also come true as a by-product. This thesis investigates searchable encryption technologies in cloud storage and distributed systems and spares effort to address the problems mentioned above. Our first work can be classified into SSE. We formulate the Multi-user Verifiable Searchable Symmetric Encryption (MVSSE) and propose a concrete scheme for multi-user access. It not only offers multi-user access and verifiability but also supports extension on updates as well as a non-single keyword index. Moreover, revocable access control is obtained that the search authority is validated each time a query is launched, different from existing mechanisms that once the search authority is granted, users can search forever. We give simulation-based proof, demonstrating our proposal possesses Universally Composable (UC)-security. Second, we come up with a redundancy elimination solution on top of searchable encryption. Following the keyword comparison approach of SSE, we formulate a hybrid primitive called Message-Locked Searchable Encryption (MLSE) derived in the way of SSE’s keyword search supporting keyword search and deduplication and present a concrete construction that enables multi-keyword query and negative keyword query as well as deduplication at a considerable small cost, i.e., the tokens are used for both search and deduplication. And it can further support Proof of Storage (PoS), testifying the content integrity in cloud storage. The semantic security is proved in Random Oracle Model using the game-based methodology. Third, as the branch of PEKS, the Broadcast Authenticated Encryption with Keyword Search (BAEKS) is proposed to bridge the gap of multi-reader access for PEKS, followed by a scheme. It not only resists Keyword Guessing Attacks (KGA) but also fills in the blank of anonymity. The scheme is proved secure under Decisional Bilinear Diffie-Hellman (DBDH) assumption in the Random Oracle Model. For distributed systems, we present a Searchable Encryption based on Efficient Privacy-preserving Outsourced calculation framework with Multiple keys (SE-EPOM) enjoying desirable features, which can be classified into PEKS. Instead of merely deploying a single server, multiple servers are employed to execute the test algorithm in our scheme jointly. The refined search, i.e., multi-keyword query, data confidentiality, and search pattern hiding, are realized. Besides, the multi-writer/multi-reader mode comes true. It is shown that under the distributed circumstance, much efficiency can be substantially achieved by our construction. With simulation-based proof, the security of our scheme is elaborated. All constructions proposed in this thesis are formally proven according to their corresponding security definitions and requirements. In addition, for each cryptographic primitive designed in this thesis, concrete schemes are initiated to demonstrate the availability and practicality of our proposal

Verifiable Encryption from MPC-in-the-Head

Verifiable encryption (VE) is a protocol where one can provide assurance that an encrypted plaintext satisfies certain properties. It is an important buiding block in cryptography with many useful applications, such as key escrow, group signatures, optimistic fair exchange, etc. However, a majority of previous VE schemes are restricted to instantiation with specific public-key encryption schemes or relations. In this work, we propose a novel framework that realizes VE protocols using the MPC-in-the-head zero-knowledge proof systems (Ishai et al. STOC 2007). Our generic compiler can turn a large class of MPC-in-the-head ZK proofs into secure VE protocols for any CPA secure public-key encryption (PKE) schemes with the undeniability property, a notion that essentially guarantees binding of encryption when used as a commitment scheme. Our framework is versatile: because the circuit proven by the MPC-in-the-head prover is decoupled from a complex encryption function, the prover’s work can be focused on proving properties (i.e. relation) about the encrypted data, not the proof of plaintext knowledge. Hence, our approach allows for instantiation with various combinations of properties about encrypted data and encryption functions. As concrete applications we describe new approaches to verifiably encrypting discrete logarithms in any prime order group and AES private keys