Transformations of CCP programs

Etalle, Sandro; Gabbrielli, Maurizio; Meo, Maria Chiara

doi:10.1145/503502.503504

Cited by 17 publications

(18 citation statements)

References 28 publications

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“…This step could be extended in several directions: First of all, the unfolding operation could be extended to take into account also the constraints in the propagation part of the head of a rule. Also, we could extend to CHR some of the other transformations, notably folding (Tamaki and Sato 1984) which has already been applied to CCP in (Etalle et al 2001). Finally, we would like to investigate from a practical perspective to what extent program transformation can improve the performance of the CHR solver.…”

Section: Discussionmentioning

confidence: 99%

Unfolding for CHR programs

Gabbrielli

Meo

Tacchella

et al. 2013

Theory and Practice of Logic Programming

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Program transformation is an appealing technique which allows to improve run-time efficiency, space-consumption, and more generally to optimize a given program. Essentially, it consists of a sequence of syntactic program manipulations which preserves some kind of semantic equivalence. Unfolding is one of the basic operations which is used by most program transformation systems and which consists in the replacement of a procedure call by its definition. While there is a large body of literature on transformation and unfolding of sequential programs, very few papers have addressed this issue for concurrent languages.This paper defines an unfolding system for CHR programs. We define an unfolding rule, show its correctness and discuss some conditions which can be used to delete an unfolded rule while preserving the program meaning. We also prove that, under some suitable conditions, confluence and termination are preserved by the above transformation.

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Section: Discussionmentioning

confidence: 99%

Unfolding for CHR programs

Gabbrielli

Meo

Tacchella

et al. 2013

Theory and Practice of Logic Programming

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“…Since CHR can be seen as an extension of concurrent constraint programming (CCP) [SR90] by multiple heads (multi-sets) and propagation rules, literature on program transformation for concurrent constraint and logicbased programming languages is relevant: [EGM01] deals with transformations of concurrent constraint logic programs, [FPP04] deals with constraint logic programs (CLP), and [UF88] deals with a guarded concurrent logic programming language called GHC.…”

Section: Constraint Handling Rules (Chr)mentioning

confidence: 99%

“…-In concurrent languages like CHR, we also can eliminate communication channels, synchronization points and don't care nondeterminism [EGM01]. -Verification and model checking can be done by program transformation [DP99,FPP01,RKRR04].…”

Section: Introductionmentioning

confidence: 99%

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Specialization of Concurrent Guarded Multi-set Transformation Rules

Frühwirth

2005

Logic Based Program Synthesis and Transformation

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Abstract. Program transformation and in particular partial evaluation are appealing techniques for declarative programs to improve not only their performance. This paper presents the first step towards developing program transformation techniques for a concurrent constraint programming language where guarded rules rewrite and augment multi-sets of atomic formulae, called Constraint Handling Rules (CHR). We study the specialization of rules with regard to a given goal (query). We show the correctness of this program transformation: Adding and removing specialized rules in a program does not change the program's operational semantics. Furthermore termination and confluence of the program are shown to be preserved.

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“…Indeed, standard semantics for concurrent logic languages such as CCP [13,25] and GHC [31] often capture such intermediate results, or in any case, the results of non-successful computations [11]. In fact, input consuming programs can have a reactive nature: the (partial) result of a computation may trigger another computation by instantiating sufficiently the input positions of another atom so that it becomes resolvable.…”

Section: A Denotational Semantics For Partial Derivationsmentioning

confidence: 99%

Termination of simply moded logic programs with dynamic scheduling

Bossi

Etalle

Rossi

et al. 2004

ACM Trans. Comput. Logic

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In logic programming, dynamic scheduling indicates the feature by means of which the choice of the atom to be selected at each resolution step is done at runtime and does not follow a fixed selection rule such as the leftto-right one of Prolog. Input consuming derivations were introduced to model dynamic scheduling while abstracting from the technical details. In this article, we provide a sufficient and necessary criterion for termination of input consuming derivations of simply moded logic programs. The termination criterion we propose is based on a denotational semantics for partial derivations which is defined in the spirit of model-theoretic semantics previously proposed for left-to-right derivations.

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Transformations of CCP programs

Cited by 17 publications

References 28 publications

Unfolding for CHR programs

Unfolding for CHR programs

Specialization of Concurrent Guarded Multi-set Transformation Rules

Termination of simply moded logic programs with dynamic scheduling

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