Compiler

About: Compiler is a research topic. Over the lifetime, 26362 publications have been published within this topic receiving 578585 citations. The topic is also known as: code compiler & Compiler.

Advanced Compiler Design and Implementation

Abstract: Advanced Compiler Design and Implementation by Steven Muchnick Preface 1 Introduction to Advanced Topics 1.1 Review of Compiler Structure 1.2 Advanced Issues in Elementary Topics 1.3 The Importance of Code Optimization 1.4 Structure of Optimizing Compilers 1.5 Placement of Optimizations in Aggressive Optimizing Compilers 1.6 Reading Flow Among the Chapters 1.7 Related Topics Not Covered in This Text 1.8 Target Machines Used in Examples 1.9 Number Notations and Data Sizes 1.10 Wrap-Up 1.11 Further Reading 1.12 Exercises 2 Informal Compiler Algorithm Notation (ICAN) 2.1 Extended Backus-Naur Form Syntax Notation 2.2 Introduction to ICAN 2.3 A Quick Overview of ICAN 2.4 Whole Programs 2.5 Type Definitions 2.6 Declarations 2.7 Data Types and Expressions 2.8 Statements 2.9 Wrap-Up 2.10 Further Reading 2.11 Exercises 3 Symbol-Table Structure 3.1 Storage Classes, Visibility, and Lifetimes 3.2 Symbol Attributes and Symbol-Table Entries 3.3 Local Symbol-Table Management 3.4 Global Symbol-Table Structure 3.5 Storage Binding and Symbolic Registers 3.6 Approaches to Generating Loads and Stores 3.7 Wrap-Up 3.8 Further Reading 3.9 Exercises 4 Intermediate Representations 4.1 Issues in Designing an Intermediate Language 4.2 High-Level Intermediate Languages 4.3 Medium-Level Intermediate Languages 4.4 Low-Level Intermediate Languages 4.5 Multi-Level Intermediate Languages 4.6 Our Intermediate Languages: MIR, HIR, and LIR 4.7 Representing MIR, HIR, and LIR in ICAN 4.8 ICAN Naming of Data Structures and Routines that Manipulate Intermediate Code 4.9 Other Intermediate-Language Forms 4.10 Wrap-Up 4.11 Further Reading 4.12 Exercises 5 Run-Time Support 5.1 Data Representations and Instructions 5.2 Register Usage 5.3 The Local Stack Frame 5.4 The Run-Time Stack 5.5 Parameter-Passing Disciplines 5.6 Procedure Prologues, Epilogues, Calls, and Returns 5.7 Code Sharing and Position-Independent Code 5.8 Symbolic and Polymorphic Language Support 5.9 Wrap-Up 5.10 Further Reading 5.11 Exercises 6 Producing Code Generators Automatically 6.1 Introduction to Automatic Generation of Code Generators 6.2 A Syntax-Directed Technique 6.3 Introduction to Semantics-Directed Parsing 6.4 Tree Pattern Matching and Dynamic Programming 6.5 Wrap-Up 6.6 Further Reading 6.7 Exercises 7 Control-Flow Analysis 7.1 Approaches to Control-Flow Analysis 7.2 Depth-First Search, Preorder Traversal, Postorder Traversal, and Breadth-First Search 7.3 Dominators 7.4 Loops and Strongly Connected Components 7.5 Reducibility 7.6 Interval Analysis and Control Trees 7.7 Structural Analysis 7.8 Wrap-Up 7.9 Further Reading 7.10 Exercises 8 Data-Flow Analysis 8.1 An Example: Reaching Definitions 8.2 Basic Concepts: Lattices, Flow Functions, and Fixed Points 8.3 Taxonomy of Data-Flow Problems and Solution Methods 8.4 Iterative Data-Flow Analysis 8.5 Lattices of Flow Functions 8.6 Control-Tree-Based Data-Flow Analysis 8.7 Structural Analysis 8.8 Interval Analysis 8.9 Other Approaches 8.10 Du-Chains, Ud-Chains, and Webs 8.11 Static Single-Assignment (SSA) Form 8.12 Dealing with Arrays, Structures, and Pointers 8.13 Automating Construction of Data-Flow Analyzers 8.14 More Ambitious Analyses 8.15 Wrap-Up 8.16 Further Reading 8.17 Exercises 9 Dependence Analysis and Dependence Graph 9.1 Dependence Relations 9.2 Basic-Block Dependence DAGs 9.3 Dependences in Loops 9.4 Dependence Testing 9.5 Program-Dependence Graphs 9.6 Dependences Between Dynamically Allocated Objects 9.7 Wrap-Up 9.8 Further Reading 9.9 Exercises 10 Alias Analysis 10.1 Aliases in Various Real Programming Languages 10.2 The Alias Gatherer 10.3 The Alias Propagator 10.4 Wrap-Up 10.5 Further Reading 10.6 Exercises 11 Introduction to Optimization 11.1 Global Optimizations Discussed in Chapters 12 Through 18 11.2 Flow Sensitivity and May vs. Must Information 11.3 Importance of Individual Optimizations 11.4 Order and Repetition of Optimizations 11.5 Further Reading 11.6 Exercises 12 Early Optimizations 12.1 Constant-Expression Evaluation (Constant Folding) 12.2 Scalar Replacement of Aggregates 12.3 Algebraic Simplifications and Reassociation 12.4 Value Numbering 12.5 Copy Propagation 12.6 Sparse Conditional Constant Propagation 12.7 Wrap-Up 12.8 Further Reading 12.9 Exercises 13 Redundancy Elimination 13.1 Common-Subexpression Elimination 13.2 Loop-Invariant Code Motion 13.3 Partial-Redundancy Elimination 13.4 Redundancy Elimination and Reassociation 13.5 Code Hoisting 13.6 Wrap-Up 13.7 Further Reading 13.8 Exercises 14 Loop Optimizations 14.1 Induction-Variable Optimizations 14.2 Unnecessary Bounds-Checking Elimination 14.3 Wrap-Up 14.4 Further Reading 14.5 Exercises 15 Procedure Optimizations 15.1 Tail-Call Optimization and Tail-Recursion Elimination 15.2 Procedure Integration 15.3 In-Line Expansion 15.4 Leaf-Routine Optimization and Shrink Wrapping 15.5 Wrap-Up 15.6 Further Reading 15.7 Exercises 16 Register Allocation 16.1 Register Allocation and Assignment 16.2 Local Methods 16.3 Graph Coloring 16.4 Priority-Based Graph Coloring 16.5 Other Approaches to Register Allocation 16.6 Wrap-Up 16.7 Further Reading 16.8 Exercises 17 Code Scheduling 17.1 Instruction Scheduling 17.2 Speculative Loads and Boosting 17.3 Speculative Scheduling 17.4 Software Pipelining 17.5 Trace Scheduling 17.6 Percolation Scheduling 17.7 Wrap-Up 17.8 Further Reading 17.9 Exercises 18 Control-Flow and Low-Level Optimizations 18.1 Unreachable-Code Elimination 18.2 Straightening 18.3 If Simplifications 18.4 Loop Simplifications 18.5 Loop Inversion 18.6 Unswitching 18.7 Branch Optimizations 18.8 Tail Merging or Cross Jumping 18.9 Conditional Moves 18.10 Dead-Code Elimination 18.11 Branch Prediction 18.12 Machine Idioms and Instruction Combining 18.13 Wrap-Up 18.14 Further Reading 18.15 Exercises 19 Interprocedural Analysis and Optimization 19.1 Interprocedural Control-Flow Analysis: The Call Graph 19.2 Interprocedural Data-Flow Analysis 19.3 Interprocedural Constant Propagation 19.4 Interprocedural Alias Analysis 19.5 Interprocedural Optimizations 19.6 Interprocedural Register Allocation 19.7 Aggregation of Global References 19.8 Other Issues in Interprocedural Program Management 19.9 Wrap-Up 19.10 Further Reading 19.11 Exercises 20 Optimization of the Memory Hierarchy 20.1 Impact of Data and Instruction Caches 20.2 Instruction-Cache Optimization 20.3 Scalar Replacement of Array Elements 20.4 Data-Cache Optimization 20.5 Scalar vs. Memory-Oriented Optimizations 20.6 Wrap-Up 20.7 Further Reading 20.8 Exercises 21 Case Studies of Compilers and Future Trends 21.1 the Sun Compilers for SPARC 21.2 The IBM XL Compilers for the POWER and PowerPC Architectures 21.3 Digital Equipment's Compilers for Alpha 21.4 The Intel Reference Compilers for the Intel 386 Architecture 21.5 Future Trends in Compiler Design and Implementation 21.6 Further Reading A Guide to Assembly Languages Used in This Book A.1 Sun SPARC Versions 8 and 9 Assembly Language A.2 IBM POWER and PowerPC Assembly Language A.3 DEC Alpha Assembly Language A.4 Intel 386 Architecture Assembly Language A.5 Hewlett-Packard's PA-RISC Assembly Language B Representation of Sets, Sequences, Trees, DAGs, and Functions B.1 Representation of Sets B.2 Representation of Sequences B.3 Representation of Trees and DAGs B.4 Representation of Functions B.5 Further Reading C Software Resources View Appendix C with live links to download sites C.1 Finding and Accessing Software on the Internet C.2 Machine Simulators C.3 Compilers C.4 Code-Generator Generators: BURG and IBURG C.5 Profiling Tools Bibliography Indices

Object-oriented modeling and design

Abstract: 1. Introduction. I. MODELING CONCEPTS. 2. Modeling as a Design Technique. 3. Object Modeling. 4. Advanced Object Modeling. 5. Dynamic Modeling. 6. Functional Modeling. II. DESIGN METHODOLOGY. 7. Methodology Preview. 8. Analysis. 9. System Design. 10. Object Design. 11. Methodology Summary. 12. Comparison of Methodologies. III. IMPLEMENTATION. 13. From Design to Implementation. 14. Programming Style. 15. Object-Oriented Languages. 16. Non-Object-Oriented Languages. 17. Databases. 18. Object Diagram Compiler. 19. Computer Animation. 20. Electrical Distribution Design System. 21. Future of Object-Oriented Technology. Appendix A: OMT Graphical Notation. Appendix B: Glossary. Index.

MediaBench: a tool for evaluating and synthesizing multimedia and communications systems

Abstract: Significant advances have been made in compilation technology for capitalizing on instruction-level parallelism (ILP). The vast majority of ILP compilation research has been conducted in the context of general-purpose computing, and more specifically the SPEC benchmark suite. At the same time, a number of microprocessor architectures have emerged which have VLIW and SIMD structures that are well matched to the needs of the ILP compilers. Most of these processors are targeted at embedded applications such as multimedia and communications, rather than general-purpose systems. Conventional wisdom, and a history of hand optimization of inner-loops, suggests that ILP compilation techniques are well suited to these applications. Unfortunately, there currently exists a gap between the compiler community and embedded applications developers. This paper presents MediaBench, a benchmark suite that has been designed to fill this gap. This suite has been constructed through a three-step process: intuition and market driven initial selection, experimental measurement to establish uniqueness, and integration with system synthesis algorithms to establish usefulness.

Principles of program analysis

Abstract: Program analysis utilizes static techniques for computing reliable information about the dynamic behavior of programs. Applications include compilers (for code improvement), software validation (for detecting errors) and transformations between data representation (for solving problems such as Y2K). This book is unique in providing an overview of the four major approaches to program analysis: data flow analysis, constraint-based analysis, abstract interpretation, and type and effect systems. The presentation illustrates the extensive similarities between the approaches, helping readers to choose the best one to utilize.