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Write High-Performance, Highly Scalable Multicore Applications for Leading Platforms
Multicore Application Programming is a comprehensive, practical guide to high-performance multicore programming that any experienced developer can use.
Author Darryl Gove covers the leading approaches to parallelization on Windows, Linux, and Oracle Solaris. Through practical examples, he illuminates the challenges involved in writing applications that fully utilize multicore processors, helping you produce applications that are functionally correct, offer superior performance, and scale well to eight cores, sixteen cores, and beyond.
The book reveals how specific hardware implementations impact application performance and shows how to avoid common pitfalls. Step by step, you’ll write applications that can handle large numbers of parallel threads, and you’ll master advanced parallelization techniques. You’ll learn how to
Multicore Application Programming isn’t wedded to a single approach or platform: It is for every experienced C programmer working with any contemporary multicore processor in any leading operating system environment.
Multicore Application Programming: An Interview with Darryl Gove
Multicore Application Programming: Identifying Opportunities for Parallelism
Download the sample pages (includes Chapter 3 and Index)
Preface xv
Acknowledgments xix
About the Author xxi
Chapter 1: Hardware, Processes, and Threads 1
Examining the Insides of a Computer 1
The Motivation for Multicore Processors 3
The Characteristics of Multiprocessor Systems 18
The Translation of Source Code to Assembly Language 21
Summary 29
Chapter 2: Coding for Performance 31
Defining Performance 31
Understanding Algorithmic Complexity 33
How Structure Impacts Performance 39
The Role of the Compiler 60
Identifying Where Time Is Spent Using Profiling 74
How Not to Optimize 80
Performance by Design 82
Summary 83
Chapter 3: Identifying Opportunities for Parallelism 85
Using Multiple Processes to Improve System Productivity 85
Multiple Users Utilizing a Single System 87
Improving Machine Efficiency Through Consolidation 88
Using Parallelism to Improve the Performance of a Single Task 92
Parallelization Patterns 100
How Dependencies Influence the Ability Run Code in Parallel 110
Identifying Parallelization Opportunities 118
Summary 119
Chapter 4: Synchronization and Data Sharing 121
Data Races 121
Synchronization Primitives 126
Deadlocks and Livelocks 132
Communication Between Threads and Processes 133
Storing Thread-Private Data 141
Summary 142
Chapter 5: Using POSIX Threads 143
Creating Threads 143
Compiling Multithreaded Code 151
Process Termination 153
Sharing Data Between Threads 154
Variables and Memory 175
Multiprocess Programming 179
Sockets 193
Reentrant Code and Compiler Flags 197
Summary 198
Chapter 6: Windows Threading 199
Creating Native Windows Threads 199
Methods of Synchronization and Resource Sharing 208
Wide String Handling in Windows 221
Creating Processes 222
Atomic Updates of Variables 238
Allocating Thread-Local Storage 240
Setting Thread Priority 242
Summary 244
Chapter 7: Using Automatic Parallelization and OpenMP 245
Using Automatic Parallelization to Produce a Parallel Application 245
Using OpenMP to Produce a Parallel Application 256
Ensuring That Code in a Parallel Region Is Executed in Order 285
Collapsing Loops to Improve Workload Balance 286
Enforcing