28,768 research outputs found
Inferring Termination Conditions for Logic Programs using Backwards Analysis
This paper focuses on the inference of modes for which a logic program is
guaranteed to terminate. This generalises traditional termination analysis
where an analyser tries to verify termination for a specified mode. Our
contribution is a methodology in which components of traditional termination
analysis are combined with backwards analysis to obtain an analyser for
termination inference. We identify a condition on the components of the
analyser which guarantees that termination inference will infer all modes which
can be checked to terminate. The application of this methodology to enhance a
traditional termination analyser to perform also termination inference is
demonstrated
The CIAO multiparadigm compiler and system: A progress report
Abstract is not available
Transforming floundering into success
We show how logic programs with "delays" can be transformed to programs
without delays in a way which preserves information concerning floundering
(also known as deadlock). This allows a declarative (model-theoretic),
bottom-up or goal independent approach to be used for analysis and debugging of
properties related to floundering. We rely on some previously introduced
restrictions on delay primitives and a key observation which allows properties
such as groundness to be analysed by approximating the (ground) success set.
This paper is to appear in Theory and Practice of Logic Programming (TPLP).
Keywords: Floundering, delays, coroutining, program analysis, abstract
interpretation, program transformation, declarative debuggingComment: Number of pages: 24 Number of figures: 9 Number of tables: non
The CIAO Multi-Dialect Compiler and System: An Experimentation Workbench for Future (C)LP Systems
CIAO is an advanced programming environment supporting Logic and Constraint programming. It offers a simple concurrent kernel on top of which declarative and non-declarative extensions are added via librarles. Librarles are available for supporting the ISOProlog standard, several constraint domains, functional and higher order programming, concurrent and distributed programming, internet programming, and others. The source language allows declaring properties of predicates via assertions, including types and modes. Such properties are checked at compile-time or at run-time. The compiler and system architecture are designed to natively support modular global analysis, with the two objectives of proving properties in assertions and performing program optimizations, including transparently exploiting parallelism in programs. The purpose of this paper is to report on recent progress made in the context of the CIAO system, with special emphasis on the capabilities of the compiler, the techniques used for supporting such capabilities, and the results in the áreas of program analysis and transformation already obtained with the system
Specifying and Executing Optimizations for Parallel Programs
Compiler optimizations, usually expressed as rewrites on program graphs, are
a core part of all modern compilers. However, even production compilers have
bugs, and these bugs are difficult to detect and resolve. The problem only
becomes more complex when compiling parallel programs; from the choice of graph
representation to the possibility of race conditions, optimization designers
have a range of factors to consider that do not appear when dealing with
single-threaded programs. In this paper we present PTRANS, a domain-specific
language for formal specification of compiler transformations, and describe its
executable semantics. The fundamental approach of PTRANS is to describe program
transformations as rewrites on control flow graphs with temporal logic side
conditions. The syntax of PTRANS allows cleaner, more comprehensible
specification of program optimizations; its executable semantics allows these
specifications to act as prototypes for the optimizations themselves, so that
candidate optimizations can be tested and refined before going on to include
them in a compiler. We demonstrate the use of PTRANS to state, test, and refine
the specification of a redundant store elimination optimization on parallel
programs.Comment: In Proceedings GRAPHITE 2014, arXiv:1407.767
A Vision of Collaborative Verification-Driven Engineering of Hybrid Systems
Abstract. Hybrid systems with both discrete and continuous dynamics are an important model for real-world physical systems. The key challenge is how to ensure their correct functioning w.r.t. safety requirements. Promising techniques to ensure safety seem to be model-driven engineering to develop hybrid systems in a well-defined and traceable manner, and formal verification to prove their correctness. Their combination forms the vision of verification-driven engineering. Despite the remarkable progress in automating formal verification of hybrid systems, the construction of proofs of complex systems often requires significant human guidance, since hybrid systems verification tools solve undecidable problems. It is thus not uncommon for verification teams to consist of many players with diverse expertise. This paper introduces a verification-driven engineering toolset that extends our previous work on hybrid and arithmetic verification with tools for (i) modeling hybrid systems, (ii) exchanging and comparing models and proofs, and (iii) managing verification tasks. This toolset makes it easier to tackle large-scale verification tasks.
Collaborative Verification-Driven Engineering of Hybrid Systems
Hybrid systems with both discrete and continuous dynamics are an important
model for real-world cyber-physical systems. The key challenge is to ensure
their correct functioning w.r.t. safety requirements. Promising techniques to
ensure safety seem to be model-driven engineering to develop hybrid systems in
a well-defined and traceable manner, and formal verification to prove their
correctness. Their combination forms the vision of verification-driven
engineering. Often, hybrid systems are rather complex in that they require
expertise from many domains (e.g., robotics, control systems, computer science,
software engineering, and mechanical engineering). Moreover, despite the
remarkable progress in automating formal verification of hybrid systems, the
construction of proofs of complex systems often requires nontrivial human
guidance, since hybrid systems verification tools solve undecidable problems.
It is, thus, not uncommon for development and verification teams to consist of
many players with diverse expertise. This paper introduces a
verification-driven engineering toolset that extends our previous work on
hybrid and arithmetic verification with tools for (i) graphical (UML) and
textual modeling of hybrid systems, (ii) exchanging and comparing models and
proofs, and (iii) managing verification tasks. This toolset makes it easier to
tackle large-scale verification tasks
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