63,953 research outputs found
A Complete Axiomatization of Quantified Differential Dynamic Logic for Distributed Hybrid Systems
We address a fundamental mismatch between the combinations of dynamics that
occur in cyber-physical systems and the limited kinds of dynamics supported in
analysis. Modern applications combine communication, computation, and control.
They may even form dynamic distributed networks, where neither structure nor
dimension stay the same while the system follows hybrid dynamics, i.e., mixed
discrete and continuous dynamics. We provide the logical foundations for
closing this analytic gap. We develop a formal model for distributed hybrid
systems. It combines quantified differential equations with quantified
assignments and dynamic dimensionality-changes. We introduce a dynamic logic
for verifying distributed hybrid systems and present a proof calculus for this
logic. This is the first formal verification approach for distributed hybrid
systems. We prove that our calculus is a sound and complete axiomatization of
the behavior of distributed hybrid systems relative to quantified differential
equations. In our calculus we have proven collision freedom in distributed car
control even when an unbounded number of new cars may appear dynamically on the
road
Session Types in Abelian Logic
There was a PhD student who says "I found a pair of wooden shoes. I put a
coin in the left and a key in the right. Next morning, I found those objects in
the opposite shoes." We do not claim existence of such shoes, but propose a
similar programming abstraction in the context of typed lambda calculi. The
result, which we call the Amida calculus, extends Abramsky's linear lambda
calculus LF and characterizes Abelian logic.Comment: In Proceedings PLACES 2013, arXiv:1312.221
Reversing Single Sessions
Session-based communication has gained a widespread acceptance in practice as
a means for developing safe communicating systems via structured interactions.
In this paper, we investigate how these structured interactions are affected by
reversibility, which provides a computational model allowing executed
interactions to be undone. In particular, we provide a systematic study of the
integration of different notions of reversibility in both binary and multiparty
single sessions. The considered forms of reversibility are: one for completely
reversing a given session with one backward step, and another for also
restoring any intermediate state of the session with either one backward step
or multiple ones. We analyse the costs of reversing a session in all these
different settings. Our results show that extending binary single sessions to
multiparty ones does not affect the reversibility machinery and its costs
Affine Sessions
Session types describe the structure of communications implemented by
channels. In particular, they prescribe the sequence of communications, whether
they are input or output actions, and the type of value exchanged. Crucial to
any language with session types is the notion of linearity, which is essential
to ensure that channels exhibit the behaviour prescribed by their type without
interference in the presence of concurrency. In this work we relax the
condition of linearity to that of affinity, by which channels exhibit at most
the behaviour prescribed by their types. This more liberal setting allows us to
incorporate an elegant error handling mechanism which simplifies and improves
related works on exceptions. Moreover, our treatment does not affect the
progress properties of the language: sessions never get stuck
Multiparty Sessions based on Proof Nets
We interpret Linear Logic Proof Nets in a term language based on Solos
calculus. The system includes a synchronisation mechanism, obtained by a
conservative extension of the logic, that enables to define non-deterministic
behaviours and multiparty sessions.Comment: In Proceedings PLACES 2014, arXiv:1406.331
Session Types for Broadcasting
Up to now session types have been used under the assumptions of point to
point communication, to ensure the linearity of session endpoints, and reliable
communication, to ensure send/receive duality. In this paper we define a
session type theory for broadcast communication semantics that by definition do
not assume point to point and reliable communication. Our session framework
lies on top of the parametric framework of broadcasting psi-calculi, giving
insights on developing session types within a parametric framework. Our session
type theory enjoys the properties of soundness and safety. We further believe
that the solutions proposed will eventually provide a deeper understanding of
how session types principles should be applied in the general case of
communication semantics.Comment: In Proceedings PLACES 2014, arXiv:1406.331
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