Susan L. Graham scite author profile

In the last three decades a large number of compiler transformations for optimizing programs have been implemented. Most optimizations for uniprocessors reduce the number of instructions executed by the program using transformations based on the analysis of scalar quantities and data-flow techniques. In contrast, optimizations for high-performance superscalar, vector, and parallel processors maximize parallelism and memory locality with transformations that rely on tracking the properties of arrays using loop dependence analysis. This survey is a comprehensive overview of the important high-level program restructuring techniques for imperative languages, such as C and Fortran. Transformations for both sequential and various types of parallel architectures are covered in depth. We describe the purpose of each transformation, explain how to determine if it is legal, and give an example of its application. Programmers wishing to enhance the performance of their code can use this survey to improve their understanding of the optimizations that compilers can perform, or as a reference for techniques to be applied manually. Students can obtain an overview of optimizing compiler technology. Compiler writers can use this survey as a reference for most of the important optimizations developed to date, and as bibliographic reference for the details of each optimization. Readers are expected to be familiar with modern computer architecture and basic program compilation techniques.

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Efficient software-based fault isolation

Wahbe

et al. 1993

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Efficient software-based fault isolation

Wahbe

Lucco

Anderson

et al. 1993

SIGOPS Oper. Syst. Rev.

323

258

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Titanium: a high-performance Java dialect

Yelick

Semenzato

Pike

et al. 1998

Concurrency: Pract. Exper.

332

203

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Titanium is a language and system for high‐performance parallel scientific computing. Titanium uses Java as its base, thereby leveraging the advantages of that language and allowing us to focus attention on parallel computing issues. The main additions to Java are immutable classes, multidimensional arrays, an explicitly parallel SPMD model of computation with a global address space, and zone‐based memory management. We discuss these features and our design approach, and report progress on the development of Titanium, including our current driving application: a three‐dimensional adaptive mesh refinement parallel Poisson solver. © 1998 John Wiley & Sons, Ltd.

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Susan L. Graham

Compiler transformations for high-performance computing

Efficient software-based fault isolation

Efficient software-based fault isolation

Titanium: a high-performance Java dialect

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