Your search keyword '"Lefaucheux, Engel"' showing total 19 results

1. Execution-time opacity problems in one-clock parametric timed automata

Author

André, Étienne, Arcile, Johan, and Lefaucheux, Engel

Subjects

Computer Science - Formal Languages and Automata Theory

Abstract

Parametric timed automata (PTAs) extend the concept of timed automata, by allowing timing delays not only specified by concrete values but also by parameters, allowing the analysis of systems with uncertainty regarding timing behaviors. The full execution-time opacity is defined as the problem in which an attacker must never be able to deduce whether some private location was visited, by only observing the execution time. The problem of full ET-opacity emptiness (i.e., the emptiness over the parameter valuations for which full execution-time opacity is satisfied) is known to be undecidable for general PTAs. We therefore focus here on one-clock PTAs with integer-valued parameters over dense time. We show that the full ET-opacity emptiness is undecidable for a sufficiently large number of parameters, but is decidable for a single parameter, and exact synthesis can be effectively achieved. Our proofs rely on a novel construction as well as on variants of Presburger arithmetics. We finally prove an additional decidability result on an existential variant of execution-time opacity., Comment: This is the author (and extended) version of the manuscript of the same name published in the proceedings of the 44th IARCS Annual Conference on Foundations of Software Technology and Theoretical Computer Science (FSTTCS 2024)

Published

2024

2. Execution-time opacity control for timed automata

Author

André, Étienne, Duflot, Marie, Laversa, Laetitia, and Lefaucheux, Engel

Subjects

Computer Science - Cryptography and Security

Abstract

Timing leaks in timed automata (TA) can occur whenever an attacker is able to deduce a secret by observing some timed behavior. In execution-time opacity, the attacker aims at deducing whether a private location was visited, by observing only the execution time. It can be decided whether a TA is opaque in this setting. In this work, we tackle control, and show that we are able to decide whether a TA can be controlled at runtime to ensure opacity. Our method is constructive, in the sense that we can exhibit such a controller. We also address the case when the attacker cannot have an infinite precision in its observations., Comment: This is the author (and extended) version of the manuscript of the same name published in the proceedings of the 22nd International Conference on Software Engineering and Formal Methods ({SEFM} 2024)

Published

2024

3. The Bright Side of Timed Opacity

Author

André, Étienne, Dépernet, Sarah, and Lefaucheux, Engel

Subjects

Computer Science - Logic in Computer Science, Computer Science - Cryptography and Security, Computer Science - Formal Languages and Automata Theory

Abstract

In 2009, Franck Cassez showed that the timed opacity problem, where an attacker can observe some actions with their timestamps and attempts to deduce information, is undecidable for timed automata (TAs). Moreover, he showed that the undecidability holds even for subclasses such as event-recording automata. In this article, we consider the same definition of opacity for several other subclasses of TAs: with restrictions on the number of clocks, of actions, on the nature of time, or on a new subclass called observable event-recording automata. We show that opacity can mostly be retrieved, except for one-action TAs and for one-clock TAs with $\epsilon$-transitions, for which undecidability remains. We then exhibit a new decidable subclass in which the number of observations made by the attacker is limited., Comment: This is the author (and extended) version of the manuscript of the same name published in the proceedings of the 25th International Conference on Formal Engineering Methods (ICFEM 2024)

Published

2024

4. The 2-Dimensional Constraint Loop Problem is Decidable

Author

Guilmant, Quentin, Lefaucheux, Engel, Ouaknine, Joël, and Worrell, James

Subjects

Computer Science - Logic in Computer Science

Abstract

A linear constraint loop is specified by a system of linear inequalities that define the relation between the values of the program variables before and after a single execution of the loop body. In this paper we consider the problem of determining whether such a loop terminates, i.e., whether all maximal executions are finite, regardless of how the loop is initialised and how the non-determinism in the loop body is resolved. We focus on the variant of the termination problem in which the loop variables range over $\mathbb{R}$. Our main result is that the termination problem is decidable over the reals in dimension~2. A more abstract formulation of our main result is that it is decidable whether a binary relation on $\mathbb{R}^2$ that is given as a conjunction of linear constraints is well-founded., Comment: Full version of a conference paper

Published

2024

5. Expiring opacity problems in parametric timed automata

Author

André, Étienne, Lefaucheux, Engel, and Marinho, Dylan

Subjects

Computer Science - Logic in Computer Science, Computer Science - Cryptography and Security

Abstract

Information leakage can have dramatic consequences on the security of real-time systems. Timing leaks occur when an attacker is able to infer private behavior depending on timing information. In this work, we propose a definition of expiring timed opacity w.r.t. execution time, where a system is opaque whenever the attacker is unable to deduce the reachability of some private state solely based on the execution time; in addition, the secrecy is violated only when the private state was entered "recently", i.e., within a given time bound (or expiration date) prior to system completion. This has an interesting parallel with concrete applications, notably cache deducibility: it may be useless for the attacker to know the cache content too late after its observance. We study here expiring timed opacity problems in timed automata. We consider the set of time bounds (or expiration dates) for which a system is opaque and show when they can be effectively computed for timed automata. We then study the decidability of several parameterized problems, when not only the bounds, but also some internal timing constants become timing parameters of unknown constant values., Comment: This is the author (and slightly modified) version of the manuscript of the same name published in the proceedings of the 27th International Conference on Engineering of Complex Computer Systems (ICECCS 2023). This work is partially supported by the ANR-NRF French-Singaporean research program ProMiS (ANR-19-CE25-0015 / 2019 ANR NRF 0092) and the ANR research program BisoUS (ANR-22-CE48-0012)

Published

2024

6. Configuring Timing Parameters to Ensure Execution-Time Opacity in Timed Automata

Author

André, Étienne, Lefaucheux, Engel, Lime, Didier, Marinho, Dylan, and Sun, Jun

Subjects

Computer Science - Logic in Computer Science, Computer Science - Cryptography and Security, Computer Science - Software Engineering, F.1.1, F.4.1, D.4.6

Abstract

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 works

Published

2023

7. strategFTO: Untimed control for timed opacity

Author

André, Étienne, Bolat, Shapagat, Lefaucheux, Engel, and Marinho, Dylan

Subjects

Computer Science - Cryptography and Security, Computer Science - Formal Languages and Automata Theory, Computer Science - Logic in Computer Science

Abstract

We introduce a prototype tool strategFTO addressing the verification of a security property in critical software. We consider a recent definition of timed opacity where an attacker aims to deduce some secret while having access only to the total execution time. The system, here modeled by timed automata, is deemed opaque if for any execution time, there are either no corresponding runs, or both public and private corresponding runs. We focus on the untimed control problem: exhibiting a controller, i.e., a set of allowed actions, such that the system restricted to those actions is fully timed-opaque. We first show that this problem is not more complex than the full timed opacity problem, and then we propose an algorithm, implemented and evaluated in practice., Comment: This work is partially supported by the ANR-NRF French-Singaporean research program ProMiS (ANR-19-CE25-0015 / 2019 ANR NRF 0092) and the ANR research program BisoUS. Experiments presented in this paper were carried out using the Grid'5000 testbed, supported by a scientific interest group hosted by Inria and including CNRS, RENATER and several universities as well as other organizations

Published

2022

8. Model Checking Linear Dynamical Systems under Floating-point Rounding

Author

Lefaucheux, Engel, Ouaknine, Joël, Purser, David, and Sharifi, Mohammadamin

Subjects

Computer Science - Logic in Computer Science

Abstract

We consider linear dynamical systems under floating-point rounding. In these systems, a matrix is repeatedly applied to a vector, but the numbers are rounded into floating-point representation after each step (i.e., stored as a fixed-precision mantissa and an exponent). The approach more faithfully models realistic implementations of linear loops, compared to the exact arbitrary-precision setting often employed in the study of linear dynamical systems. Our results are twofold: We show that for non-negative matrices there is a special structure to the sequence of vectors generated by the system: the mantissas are periodic and the exponents grow linearly. We leverage this to show decidability of $\omega$-regular temporal model checking against semialgebraic predicates. This contrasts with the unrounded setting, where even the non-negative case encompasses the long-standing open Skolem and Positivity problems. On the other hand, when negative numbers are allowed in the matrix, we show that the reachability problem is undecidable by encoding a two-counter machine. Again, this is in contrast with the unrounded setting where point-to-point reachability is known to be decidable in polynomial time., Comment: Long version of the TACAS 2023 paper

Published

2022

9. Bounding the Escape Time of a Linear Dynamical System over a Compact Semialgebraic Set

Author

D'Costa, Julian, Lefaucheux, Engel, Neumann, Eike, Ouaknine, Joël, and Worrell, James

Subjects

Computer Science - Computational Complexity

Abstract

We study the Escape Problem for discrete-time linear dynamical systems over compact semialgebraic sets. We establish a uniform upper bound on the number of iterations it takes for every orbit of a rational matrix to escape a compact semialgebraic set defined over rational data. Our bound is doubly exponential in the ambient dimension, singly exponential in the degrees of the polynomials used to define the semialgebraic set, and singly exponential in the bitsize of the coefficients of these polynomials and the bitsize of the matrix entries. We show that our bound is tight by providing a matching lower bound.

Published

2022

10. The boundedness and zero isolation problems for weighted automata over nonnegative rationals

Author

Czerwiński, Wojciech, Lefaucheux, Engel, Mazowiecki, Filip, Purser, David, and Whiteland, Markus A.

Subjects

Computer Science - Formal Languages and Automata Theory, Computer Science - Logic in Computer Science

Abstract

We consider linear cost-register automata (equivalent to weighted automata) over the semiring of nonnegative rationals, which generalise probabilistic automata. The two problems of boundedness and zero isolation ask whether there is a sequence of words that converge to infinity and to zero, respectively. In the general model both problems are undecidable so we focus on the copyless linear restriction. There, we show that the boundedness problem is decidable. As for the zero isolation problem we need to further restrict the class. We obtain a model, where zero isolation becomes equivalent to universal coverability of orthant vector addition systems (OVAS), a new model in the VAS family interesting on its own. In standard VAS runs are considered only in the positive orthant, while in OVAS every orthant has its own set of vectors that can be applied in that orthant. Assuming Schanuel's conjecture is true, we prove decidability of universal coverability for three-dimensional OVAS, which implies decidability of zero isolation in a model with at most three independent registers., Comment: Full versions of the LICS 2022 paper

Published

2022

11. On the Complexity of the Escape Problem for Linear Dynamical Systems over Compact Semialgebraic Sets

Author

D'Costa, Julian, Lefaucheux, Engel, Neumann, Eike, Ouaknine, Joël, and Worrell, James

Subjects

Computer Science - Computational Complexity, Computer Science - Logic in Computer Science

Abstract

We study the computational complexity of the Escape Problem for discrete-time linear dynamical systems over compact semialgebraic sets, or equivalently the Termination Problem for affine loops with compact semialgebraic guard sets. Consider the fragment of the theory of the reals consisting of negation-free $\exists \forall$-sentences without strict inequalities. We derive several equivalent characterisations of the associated complexity class which demonstrate its robustness and illustrate its expressive power. We show that the Compact Escape Problem is complete for this class.

Published

2021

12. Porous Invariants

Author

Lefaucheux, Engel, Ouaknine, Joël, Purser, David, and Worrell, James

Subjects

Computer Science - Logic in Computer Science

Abstract

We introduce the notion of porous invariants for multipath (or branching/nondeterministic) affine loops over the integers; these invariants are not necessarily convex, and can in fact contain infinitely many 'holes'. Nevertheless, we show that in many cases such invariants can be automatically synthesised, and moreover can be used to settle (non-)reachability questions for various interesting classes of affine loops and target sets., Comment: Full version of paper to appear at CAV 2021

Published

2021

13. The Orbit Problem for Parametric Linear Dynamical Systems

Author

Baier, Christel, Funke, Florian, Jantsch, Simon, Karimov, Toghrul, Lefaucheux, Engel, Luca, Florian, Ouaknine, Joël, Purser, David, Whiteland, Markus A., and Worrell, James

Subjects

Computer Science - Logic in Computer Science

Abstract

We study a parametric version of the Kannan-Lipton Orbit Problem for linear dynamical systems. We show decidability in the case of one parameter and Skolem-hardness with two or more parameters. More precisely, consider a $d$-dimensional square matrix $M$ whose entries are algebraic functions in one or more real variables. Given initial and target vectors $u,v\in \mathbb{Q}^d$, the parametric point-to-point orbit problem asks whether there exist values of the parameters giving rise to a concrete matrix $N \in \mathbb{R}^{d\times d}$, and a positive integer $n\in \mathbb{N}$, such that $N^nu = v$. We show decidability for the case in which $M$ depends only upon a single parameter, and we exhibit a reduction from the well-known Skolem Problem for linear recurrence sequences, suggesting intractability in the case of two or more parameters., Comment: Full version of the paper appearing at CONCUR 2021

Published

2021

14. Reachability in Dynamical Systems with Rounding

Author

Baier, Christel, Funke, Florian, Jantsch, Simon, Karimov, Toghrul, Lefaucheux, Engel, Ouaknine, Joël, Pouly, Amaury, Purser, David, and Whiteland, Markus A.

Subjects

Computer Science - Computational Complexity

Abstract

We consider reachability in dynamical systems with discrete linear updates, but with fixed digital precision, i.e., such that values of the system are rounded at each step. Given a matrix $M \in \mathbb{Q}^{d \times d}$, an initial vector $x\in\mathbb{Q}^{d}$, a granularity $g\in \mathbb{Q}_+$ and a rounding operation $[\cdot]$ projecting a vector of $\mathbb{Q}^{d}$ onto another vector whose every entry is a multiple of $g$, we are interested in the behaviour of the orbit $\mathcal{O}={<}[x], [M[x]],[M[M[x]]],\dots{>}$, i.e., the trajectory of a linear dynamical system in which the state is rounded after each step. For arbitrary rounding functions with bounded effect, we show that the complexity of deciding point-to-point reachability---whether a given target $y \in\mathbb{Q}^{d}$ belongs to $\mathcal{O}$---is PSPACE-complete for hyperbolic systems (when no eigenvalue of $M$ has modulus one). We also establish decidability without any restrictions on eigenvalues for several natural classes of rounding functions., Comment: To appear at FSTTCS'20

Published

2020

15. One-Clock Priced Timed Games with Negative Weights

Author

Brihaye, Thomas, Geeraerts, Gilles, Haddad, Axel, Lefaucheux, Engel, and Monmege, Benjamin

Subjects

Computer Science - Computer Science and Game Theory, Computer Science - Logic in Computer Science

Abstract

Priced timed games are two-player zero-sum games played on priced timed automata (whose locations and transitions are labeled by weights modelling the cost of spending time in a state and executing an action, respectively). The goals of the players are to minimise and maximise the cost to reach a target location, respectively. We consider priced timed games with one clock and arbitrary integer weights and show that, for an important subclass of them (the so-called simple priced timed games), one can compute, in pseudo-polynomial time, the optimal values that the players can achieve, with their associated optimal strategies. As side results, we also show that one-clock priced timed games are determined and that we can use our result on simple priced timed games to solve the more general class of so-called negative-reset-acyclic priced timed games (with arbitrary integer weights and one clock). The decidability status of the full class of priced timed games with one-clock and arbitrary integer weights still remains open., Comment: arXiv admin note: substantial text overlap with arXiv:1507.03786

Published

2020

16. On Positivity and Minimality for Second-Order Holonomic Sequences

Author

Kenison, George, Klurman, Oleksiy, Lefaucheux, Engel, Luca, Florian, Moree, Pieter, Ouaknine, Joël, Whiteland, Markus A., and Worrell, James

Subjects

Mathematics - Number Theory, Computer Science - Discrete Mathematics, 11B37, 11Y65, 68R99, G.2.1

Abstract

An infinite sequence $\langle{u_n}\rangle_{n\in\mathbb{N}}$ of real numbers is holonomic (also known as P-recursive or P-finite) if it satisfies a linear recurrence relation with polynomial coefficients. Such a sequence is said to be positive if each $u_n \geq 0$, and minimal if, given any other linearly independent sequence $\langle{v_n}\rangle_{n \in\mathbb{N}}$ satisfying the same recurrence relation, the ratio $u_n/v_n$ converges to $0$. In this paper, we focus on holonomic sequences satisfying a second-order recurrence $g_3(n)u_n = g_2(n)u_{n-1} + g_1(n)u_{n-2}$, where each coefficient $g_3, g_2,g_1 \in \mathbb{Q}[n]$ is a polynomial of degree at most $1$. We establish two main results. First, we show that deciding positivity for such sequences reduces to deciding minimality. And second, we prove that deciding minimality is equivalent to determining whether certain numerical expressions (known as periods, exponential periods, and period-like integrals) are equal to zero. Periods and related expressions are classical objects of study in algebraic geometry and number theory, and several established conjectures (notably those of Kontsevich and Zagier) imply that they have a decidable equality problem, which in turn would entail decidability of Positivity and Minimality for a large class of second-order holonomic sequences., Comment: 38 pages

Published

2020

17. How Fast Can You Escape a Compact Polytope?

Author

D'Costa, Julian, Lefaucheux, Engel, Ouaknine, Joël, and Worrell, James

Subjects

Mathematics - Dynamical Systems

Abstract

The Continuous Polytope Escape Problem (CPEP) asks whether every trajectory of a linear differential equation initialised within a convex polytope eventually escapes the polytope. We provide a polynomial-time algorithm to decide CPEP for compact polytopes. We also establish a quantitative uniform upper bound on the time required for every trajectory to escape the given polytope. In addition, we establish iteration bounds for termination of discrete linear loops via reduction to the continuous case., Comment: Long version of a STACS 2020 paper

Published

2020

18. On the Monniaux Problem in Abstract Interpretation

Author

Fijalkow, Nathanaël, Lefaucheux, Engel, Ohlmann, Pierre, Ouaknine, Joël, Pouly, Amaury, and Worrell, James

Subjects

Computer Science - Logic in Computer Science

Abstract

The Monniaux Problem in abstract interpretation asks, roughly speaking, whether the following question is decidable: given a program $P$, a safety (\emph{e.g.}, non-reachability) specification $\varphi$, and an abstract domain of invariants $\mathcal{D}$, does there exist an inductive invariant $I$ in $\mathcal{D}$ guaranteeing that program $P$ meets its specification $\varphi$. The Monniaux Problem is of course parameterised by the classes of programs and invariant domains that one considers. In this paper, we show that the Monniaux Problem is undecidable for unguarded affine programs and semilinear invariants (unions of polyhedra). Moreover, we show that decidability is recovered in the important special case of simple linear loops.

Published

2019

19. Simple Priced Timed Games Are Not That Simple

Author

Brihaye, Thomas, Geeraerts, Gilles, Haddad, Axel, Lefaucheux, Engel, and Monmege, Benjamin

Subjects

Computer Science - Computer Science and Game Theory, D.2.4, F.3.1

Abstract

Priced timed games are two-player zero-sum games played on priced timed automata (whose locations and transitions are labeled by weights modeling the costs of spending time in a state and executing an action, respectively). The goals of the players are to minimise and maximise the cost to reach a target location, respectively. We consider priced timed games with one clock and arbitrary (positive and negative) weights and show that, for an important subclass of theirs (the so-called simple priced timed games), one can compute, in exponential time, the optimal values that the players can achieve, with their associated optimal strategies. As side results, we also show that one-clock priced timed games are determined and that we can use our result on simple priced timed games to solve the more general class of so-called reset-acyclic priced timed games (with arbitrary weights and one-clock).

Published

2015