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Simulatable Channels: Extended Security that is Universally Composable and Easier to Prove

Degabriele, Jean Paul ; Fischlin, Marc (2018)
Simulatable Channels: Extended Security that is Universally Composable and Easier to Prove.
24th International Conference on the Theory and Application of Cryptology and Information Security. Brisbane, Australia (02.-06.12.2018)
doi: 10.1007/978-3-030-03332-3_19
Conference or Workshop Item, Bibliographie

Abstract

Ever since the foundational work of Goldwasser and Micali, simulation has proven to be a powerful and versatile construct for formulating security in various areas of cryptography. However security definitions based on simulation are generally harder to work with than game based definitions, often resulting in more complicated proofs. In this work we challenge this viewpoint by proposing new simulation-based security definitions for secure channels that in many cases lead to simpler proofs of security. We are particularly interested in definitions of secure channels which reflect real-world requirements, such as, protecting against the replay and reordering of ciphertexts, accounting for leakage from the decryption of invalid ciphertexts, and retaining security in the presence of ciphertext fragmentation. Furthermore we show that our proposed notion of channel simulatability implies a secure channel functionality that is universally composable. To the best of our knowledge, we are the first to study universally composable secure channels supporting these extended security goals. We conclude, by showing that the Dropbear implementation of SSH-CTR is channel simulatable in the presence of ciphertext fragmentation, and therefore also realises a universally composable secure channel. This is intended, in part, to highlight the merits of our approach over prior ones in admitting simpler security proofs in comparable settings.

Item Type: Conference or Workshop Item
Erschienen: 2018
Creators: Degabriele, Jean Paul ; Fischlin, Marc
Type of entry: Bibliographie
Title: Simulatable Channels: Extended Security that is Universally Composable and Easier to Prove
Language: English
Date: 26 October 2018
Publisher: Springer
Book Title: Advances in Cryptology - ASIACRYPT 2018
Series: Lecture Notes in Computer Science
Series Volume: 11274
Event Title: 24th International Conference on the Theory and Application of Cryptology and Information Security
Event Location: Brisbane, Australia
Event Dates: 02.-06.12.2018
DOI: 10.1007/978-3-030-03332-3_19
URL / URN: https://asiacrypt.iacr.org/2018/index.html
Abstract:

Ever since the foundational work of Goldwasser and Micali, simulation has proven to be a powerful and versatile construct for formulating security in various areas of cryptography. However security definitions based on simulation are generally harder to work with than game based definitions, often resulting in more complicated proofs. In this work we challenge this viewpoint by proposing new simulation-based security definitions for secure channels that in many cases lead to simpler proofs of security. We are particularly interested in definitions of secure channels which reflect real-world requirements, such as, protecting against the replay and reordering of ciphertexts, accounting for leakage from the decryption of invalid ciphertexts, and retaining security in the presence of ciphertext fragmentation. Furthermore we show that our proposed notion of channel simulatability implies a secure channel functionality that is universally composable. To the best of our knowledge, we are the first to study universally composable secure channels supporting these extended security goals. We conclude, by showing that the Dropbear implementation of SSH-CTR is channel simulatable in the presence of ciphertext fragmentation, and therefore also realises a universally composable secure channel. This is intended, in part, to highlight the merits of our approach over prior ones in admitting simpler security proofs in comparable settings.

Uncontrolled Keywords: Solutions, S4
Additional Information:

Vol. III

Divisions: 20 Department of Computer Science
20 Department of Computer Science > Cryptography and Complexity Theory
DFG-Collaborative Research Centres (incl. Transregio)
DFG-Collaborative Research Centres (incl. Transregio) > Collaborative Research Centres
Profile Areas
Profile Areas > Cybersecurity (CYSEC)
DFG-Collaborative Research Centres (incl. Transregio) > Collaborative Research Centres > CRC 1119: CROSSING – Cryptography-Based Security Solutions: Enabling Trust in New and Next Generation Computing Environments
Date Deposited: 18 Oct 2018 09:18
Last Modified: 27 Jul 2023 13:14
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