Embedded Computing: A VLIW Approach to Architecture, Compilers and ToolsElsevier, 2005. gada 19. janv. - 712 lappuses The fact that there are more embedded computers than general-purpose computers and that we are impacted by hundreds of them every day is no longer news. What is news is that their increasing performance requirements, complexity and capabilities demand a new approach to their design. Fisher, Faraboschi, and Young describe a new age of embedded computing design, in which the processor is central, making the approach radically distinct from contemporary practices of embedded systems design. They demonstrate why it is essential to take a computing-centric and system-design approach to the traditional elements of nonprogrammable components, peripherals, interconnects and buses. These elements must be unified in a system design with high-performance processor architectures, microarchitectures and compilers, and with the compilation tools, debuggers and simulators needed for application development. In this landmark text, the authors apply their expertise in highly interdisciplinary hardware/software development and VLIW processors to illustrate this change in embedded computing. VLIW architectures have long been a popular choice in embedded systems design, and while VLIW is a running theme throughout the book, embedded computing is the core topic. Embedded Computing examines both in a book filled with fact and opinion based on the authors many years of R&D experience. · Complemented by a unique, professional-quality embedded tool-chain on the authors' website, http://www.vliw.org/book· Combines technical depth with real-world experience · Comprehensively explains the differences between general purpose computing systems and embedded systems at the hardware, software, tools and operating system levels. · Uses concrete examples to explain and motivate the trade-offs. |
No grāmatas satura
1.–5. rezultāts no 86.
xxx. lappuse
... parallel issue group, or parallel execution group to different subcommunities. Wherever possible, we use the terms as they are used in the architecture field's dominant textbook, John Hennessy and Dave Patterson's Computer Architecture ...
... parallel issue group, or parallel execution group to different subcommunities. Wherever possible, we use the terms as they are used in the architecture field's dominant textbook, John Hennessy and Dave Patterson's Computer Architecture ...
12. lappuse
... parallel, pipelined functional units. Although most of us think of a “computer” as a system such as a PC, there are many types of embedded computing devices deployed today. Market analysts break processor cores into four broad ...
... parallel, pipelined functional units. Although most of us think of a “computer” as a system such as a PC, there are many types of embedded computing devices deployed today. Market analysts break processor cores into four broad ...
45. lappuse
... parallel. A processor using ILP has the same type of execution hardware as a normal RISC machine. In the case of a processor using ILP, however, the expected hardware may operate in parallel, or there may be more of that same execution ...
... parallel. A processor using ILP has the same type of execution hardware as a normal RISC machine. In the case of a processor using ILP, however, the expected hardware may operate in parallel, or there may be more of that same execution ...
46. lappuse
... parallel operations while the program runs; other times programs are presented to the hardware with the parallelism already arranged and specified in the programs. This chapter has five sections. The first section explores the semantics ...
... parallel operations while the program runs; other times programs are presented to the hardware with the parallelism already arranged and specified in the programs. This chapter has five sections. The first section explores the semantics ...
49. lappuse
... parallel in a way that goes beyond the most simple-minded view of what the program does, and the resulting speedup is a form of ILP. However, when people think of ILP they tend to think of two other factors that speed up programs ...
... parallel in a way that goes beyond the most simple-minded view of what the program does, and the resulting speedup is a form of ILP. However, when people think of ILP they tend to think of two other factors that speed up programs ...
Saturs
1 | |
45 | |
83 | |
Chapter 4 Architectural Structures in ISA Design | 125 |
Chapter 5 Microarchitecture Design | 179 |
Chapter 6 System Design and Simulation | 231 |
Chapter 7 Embedded Compiling and Toolchains | 287 |
Chapter 8 Compiling for VLIWs and ILP | 337 |
Chapter 9 The Runtime System | 399 |
Chapter 10 Application Design and Customization | 443 |
Chapter 11 Application Areas | 493 |
Appendix A The VEX System | 539 |
Appendix B Glossary | 607 |
Appendix C Bibliography | 631 |
Index | 661 |
Citi izdevumi - Skatīt visu
Embedded Computing: A VLIW Approach to Architecture, Compilers and Tools Joseph A. Fisher,Paolo Faraboschi,Cliff Young Ierobežota priekšskatīšana - 2005 |
Embedded Computing: A Vliw Approach to Architecture, Compilers and Tools Joseph A. Fisher,Paolo Faraboschi,Cliff Young Priekšskatījums nav pieejams - 2004 |
Bieži izmantoti vārdi un frāzes
algorithms allow assembly language basic blocks bits branch bytes cache called Chapter chip CISC cluster cmpx compiled simulator complex components compression computing cost cycle datapath debugging decoding dependences described devices disk dynamic embedded domain embedded systems encoding engineering example exception execution Figure floating-point FPGA functional units general-purpose global hardware implementation inline instruction set integrated interface issue iterations Java latency load logic loop machine memory accesses micro-SIMD microarchitecture Multiflow multiple multiprocessing opcode operands operating system optimizations parallel path performance phase pointer pragma predication prefetch problem processor core region register allocation register file require RISC run-time Section single slots software pipelining specific speculation standard superscalar target task techniques tion today’s toolchain types typically unrolling variable vector virtual memory VLIW VLIW architectures