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An object-oriented environment for control system designPhaal, P. January 1987 (has links)
No description available.
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Object-oriented divide-and-conquer for parallel processingPiper, Andrew James January 1994 (has links)
No description available.
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A technique for clarifying the implementation of relationships between objects to enhance software reuseMayes, Jeanne Audrey January 1995 (has links)
No description available.
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A graph-based framework for dynamic process systems modellingHarris, S. J. January 1998 (has links)
No description available.
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The roles of inheritance in software developmentArmstrong, James Matthew January 1991 (has links)
No description available.
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On software reusability, portability and user interface acceptability in UNIX -based aplicationsLawson, Edwin W. January 1990 (has links)
No description available.
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Detection of feature interactions in an object-oriented feature-based design systemAbdul-Razak, Ariffin January 1997 (has links)
No description available.
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Selective transparency in distributed transaction processingMcCue, Daniel Lawrence January 1992 (has links)
Object-oriented programming languages provide a powerful interface for programmers to access the mechanisms necessary for reliable distributed computing. Using inheritance and polymorphism provided by the object model, it is possible to develop a hierarchy of classes to capture the semantics and inter-relationships of various levels of functionality required for distributed transaction processing. Using multiple inheritance, application developers can selectively apply transaction properties to suit the requirements of the application objects. In addition to the specific problems of (distributed) transaction processing in an environment of persistent objects, there is a need for a unified framework, or architecture in which to place this system. To be truly effective, not only the transaction manager, but the entire transaction support environment must be described, designed and implemented in terms of objects. This thesis presents an architecture for reliable distributed processing in which the management of persistence, provision of transaction properties (e.g., concurrency control), and organisation of support services (e.g., RPC) are all gathered into a unified design based on the object model.
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Management of long-running high-performance persistent object storesPrintezis, Antonios January 2000 (has links)
No description available.
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Static analysis for incomplete object-oriented programsNguyen, Phung Hua, Computer Science & Engineering, Faculty of Engineering, UNSW January 2005 (has links)
Static analysis is significant since it provides the information about the run- time behaviour of an analysed program. Such information has many applications in compiler optimisations and software engineering tools. Interprocedural anal- ysis is a form of static analysis, which can exploit information available across procedure boundaries. The analysis is traditionally designed as whole-program analysis, which processes the entire program. However, whole-program analysis is problematic when parts of the analysed program are not available to partici- pate in analysis. In this case, a whole-program analysis has to make conservative assumptions to be able to produce safe analysis results at the expense of some possible precision loss. To improve analysis precision, an analysis can exploit the access control mechanism provided by the underlying program language. This thesis introduces a points-to analysis technique for incomplete object-oriented programs, called com- pleteness analysis, which exploits the access and modification properties of classes, methods and fields to enhance the analysis precision. Two variations of the tech- nique, compositional and sequential completeness analysis, are described. This thesis also presents a mutability analysis (MA) and MA-based side-effect analy- sis, which are based on the output of completeness analysis, to determine whether a variable is potentially modified by the execution of a program statement. The results of experiments carried out on a set of Java library packages are presented to demonstrate the improvement in analysis precision.
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