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Towards a Data Centric Approach for the Design and Verification of Cryptographic Protocols

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 Added by Roberto Metere
 Publication date 2019
and research's language is English




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We propose MetaCP, a Meta Cryptography Protocol verification tool, as an automated tool simplifying the design of security protocols through a graphical interface. The graphical interface can be seen as a modern editor of a non-relational database whose data are protocols. The information of protocols are stored in XML, enjoying a fixed format and syntax aiming to contain all required information to specify any kind of protocol. This XML can be seen as an almost semanticless language, where different plugins confer strict semantics modelling the protocol into a variety of back-end verification languages. In this paper, we showcase the effectiveness of this novel approach by demonstrating how easy MetaCP makes it to design and verify a protocol going from the graphical design to formally verified protocol using a Tamarin prover plugin. Whilst similar approaches have been proposed in the past, most famously the AVISPA Tool, no previous approach provides such as small learning curve and ease of use even for non security professionals, combined with the flexibility to integrate with the state of the art verification tools.



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We present MetaCP, a tool to aid the cryptographer throughout the process of designing and modelling a communication protocol suitable for formal verification. The crucial innovative aspect of the tool is its data-centric approach, where protocol specification is stored in a structured way rather than in natural languages to facilitate its interpretation to multiple target languages. Previous work shows a single exporting plugin (for Tamarin) which required aftermath modifications. By improving the expressiveness of the specification data structure we extend the tool to export to an additional formal language, i.e. ProVerif, as well as a C++ implementation. Starting with its modern graphical interface, MetaCP allows us to model the Diffie-Hellman key exchange, traditionally referred to as a case study, in just a few minutes. Ultimately, we use the formal tools to verify the executability and correctness of the automatically exported models. The design core of MetaCP is freely available in an online demo that provides two further sample protocols, Needham-Schroeder and Needham-Schroeder-Lowe, along with instructions to use the tool to begin modelling from scratch and to export the model to desired external languages.
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