2 research outputs found
Configuring Timing Parameters to Ensure Execution-Time Opacity in Timed Automata
Timing information leakage occurs whenever an attacker successfully deduces
confidential internal information by observing some timed information such as
events with timestamps. Timed automata are an extension of finite-state
automata with a set of clocks evolving linearly and that can be tested or
reset, making this formalism able to reason on systems involving concurrency
and timing constraints. In this paper, we summarize a recent line of works
using timed automata as the input formalism, in which we assume that the
attacker has access (only) to the system execution time. First, we address the
following execution-time opacity problem: given a timed system modeled by a
timed automaton, given a secret location and a final location, synthesize the
execution times from the initial location to the final location for which one
cannot deduce whether the secret location was visited. This means that for any
such execution time, the system is opaque: either the final location is not
reachable, or it is reachable with that execution time for both a run visiting
and a run not visiting the secret location. We also address the full
execution-time opacity problem, asking whether the system is opaque for all
execution times; we also study a weak counterpart. Second, we add timing
parameters, which are a way to configure a system: we identify a subclass of
parametric timed automata with some decidability results. In addition, we
devise a semi-algorithm for synthesizing timing parameter valuations
guaranteeing that the resulting system is opaque. Third, we report on problems
when the secret has itself an expiration date, thus defining expiring
execution-time opacity problems. We finally show that our method can also apply
to program analysis with configurable internal timings.Comment: In Proceedings TiCSA 2023, arXiv:2310.18720. This invited paper
mainly summarizes results on opacity from two recent works published in ToSEM
(2022) and at ICECCS 2023, providing unified notations and concept names for
the sake of consistency. In addition, we prove a few original results absent
from these work