Sur la conception d'un service de changement de contexte et de sa preuve dans le proto-noyau Pip

International audienceThe Pip protokernel is a kernel whose trusted computing base is reduced to its bare bones. The goal of such minimisation is twofold: reduce the attack surface and reduce the cost of the formal proof of security. In particular, multiplexing is not implemented in the kernel but in a partition whose code is executed in user mode. This of course assumes that the kernel provides minimal services dedicated to signal sending. In this paper, we describe a streamlined service designed to allow for inter-partition communication through userland structures that mimic the traditional Interrupt Descriptor Table

Proving the Absence of Microarchitectural Timing Channels

Microarchitectural timing channels are a major threat to computer security. A set of OS mechanisms called time protection was recently proposed as a principled way of preventing information leakage through such channels and prototyped in the seL4 microkernel. We formalise time protection and the underlying hardware mechanisms in a way that allows linking them to the information-flow proofs that showed the absence of storage channels in seL4.Comment: Scott Buckley and Robert Sison were joint lead author

Scaling Up Automated Verification: A Case Study and a Formalization IDE for Building High Integrity Software

Component-based software verification is a difficult challenge because developers must specify components formally and annotate implementations with suitable assertions that are amenable to automation. This research investigates the intrinsic complexity in this challenge using a component-based case study. Simultaneously, this work also seeks to minimize the extrinsic complexities of this challenge through the development and usage of a formalization integrated development environment (F-IDE) built for specifying, developing, and using verified reusable software components. The first contribution is an F-IDE built to support formal specification and automated verification of object-based software for the integrated specification and programming language RESOLVE. The F-IDE is novel, as it integrates a verifying compiler with a user-friendly interface that provides a number of amenities including responsive editing for model-based mathematical contracts and code, assistance for design by contract, verification, responsive error handling, and generation of property-preserving Java code that can be run within the F-IDE. The second contribution is a case study built using the F-IDE that involves an interplay of multiple artifacts encompassing mathematical units, component interfaces, and realizations. The object-based interfaces involved are specified in terms of new mathematical models and non-trivial theories designed to encapsulate data structures and algorithms. The components are designed to be amenable to modular verification and analysis