| Document Type
|
:
|
BL
|
| Record Number
|
:
|
854876
|
| Main Entry
|
:
|
Aamodt, Tor M.
|
| Title & Author
|
:
|
General-purpose graphics processor architectures /\ Tor M. Aamodt, Wilson Wai Lun Fung, Timothy G. Rogers.
|
| Publication Statement
|
:
|
[San Rafael, California] :: Morgan & Claypool Publishers,, [2018]
|
|
|
:
|
, ©2018
|
| Series Statement
|
:
|
Synthesis lectures on computer architecture,; #44
|
| Page. NO
|
:
|
1 online resource (xvii, 122 pages) :: illustrations
|
| ISBN
|
:
|
1627056181
|
|
|
:
|
: 9781627056182
|
|
|
:
|
9781627059237
|
|
|
:
|
9781681733586
|
| Bibliographies/Indexes
|
:
|
Includes bibliographical references (pages 103-119).
|
| Contents
|
:
|
1. Introduction -- 1.1 The landscape of computation accelerators -- 1.2 GPU hardware basics -- 1.3 A brief history of GPUs -- 1.4 Book outline.
|
|
|
:
|
2. Programming model -- 2.1 Execution model -- 2.2 GPU instruction set architectures -- 2.2.1 NVIDIA GPU instruction set architectures -- 2.2.2 AMD graphics core next instruction set architecture.
|
|
|
:
|
3. The SIMT core: instruction and register data flow -- 3.1 One-loop approximation -- 3.1.1 SIMT execution masking -- 3.1.2 SIMT deadlock and stackless SIMT architectures -- 3.1.3 Warp scheduling -- 3.2 Two-loop approximation -- 3.3 Three-loop approximation -- 3.3.1 Operand collector -- 3.3.2 Instruction replay: handling structural hazards -- 3.4 Research directions on branch divergence -- 3.4.1 Warp compaction -- 3.4.2 Intra-warp divergent path management -- 3.4.3 Adding MIMD capability -- 3.4.4 Complexity-effective divergence management -- 3.5 Research directions on scalarization and affine execution -- 3.5.1 Detection of uniform or affine variables -- 3.5.2 Exploiting uniform or affine variables in GPU -- 3.6 Research directions on register file architecture -- 3.6.1 Hierarchical register file -- 3.6.2 Drowsy state register file -- 3.6.3 Register file virtualization -- 3.6.4 Partitioned register file -- 3.6.5 RegLess.
|
|
|
:
|
4. Memory system -- 4.1 First-level memory structures -- 4.1.1 Scratchpad memory and L1 data cache -- 4.1.2 L1 texture cache -- 4.1.3 Unified texture and data cache -- 4.2 On-chip interconnection network -- 4.3 Memory partition unit -- 4.3.1 L2 cache -- 4.3.2 Atomic operations -- 4.3.3 Memory access scheduler -- 4.4 Research directions for GPU memory systems -- 4.4.1 Memory access scheduling and interconnection network design -- 4.4.2 Caching effectiveness -- 4.4.3 Memory request prioritization and cache bypassing -- 4.4.4 Exploiting inter-warp heterogeneity -- 4.4.5 Coordinated cache bypassing -- 4.4.6 Adaptive cache management -- 4.4.7 Cache prioritization -- 4.4.8 Virtual memory page placement -- 4.4.9 Data placement -- 4.4.10 Multi-chip-module GPUs.
|
|
|
:
|
5. Crosscutting research on GPU computing architectures -- 5.1 Thread scheduling -- 5.1.1 Research on assignment of threadblocks to cores -- 5.1.2 Research on cycle-by-cycle scheduling decisions -- 5.1.3 Research on scheduling multiple kernels -- 5.1.4 Fine-grain synchronization aware scheduling -- 5.2 Alternative ways of expressing parallelism -- 5.3 Support for transactional memory -- 5.3.1 Kilo TM -- 5.3.2 Warp TM and temporal conflict detection -- 5.4 Heterogeneous systems.
|
|
|
:
|
Bibliography -- Authors' biographies.
|
| Abstract
|
:
|
Originally developed to support video games, graphics processor units (GPUs) are now increasingly used for general-purpose (non-graphics) applications ranging from machine learning to mining of cryptographic currencies. GPUs can achieve improved performance and efficiency versus central processing units (CPUs) by dedicating a larger fraction of hardware resources to computation. In addition, their general-purpose programmability makes contemporary GPUs appealing to software developers in comparison to domain-specific accelerators. This book provides an introduction to those interested in studying the architecture of GPUs that support general-purpose computing. It collects together information currently only found among a wide range of disparate sources. The authors led development of the GPGPU-Sim simulator widely used in academic research on GPU architectures. The first chapter of this book describes the basic hardware structure of GPUs and provides a brief overview of their history. Chapter 2 provides a summary of GPU programming models relevant to the rest of the book. Chapter 3 explores the architecture of GPU compute cores. Chapter 4 explores the architecture of the GPU memory system. After describing the architecture of existing systems, Chapters 3 and 4 provide an overview of related research. Chapter 5 summarizes cross-cutting research impacting both the compute core and memory system. This book should provide a valuable resource for those wishing to understand the architecture of graphics processor units (GPUs) used for acceleration of general-purpose applications and to those who want to obtain an introduction to the rapidly growing body of research exploring how to improve the architecture of these GPUs.
|
| Subject
|
:
|
Computer architecture.
|
| Subject
|
:
|
Graphics processing units.
|
| Subject
|
:
|
Computer architecture.
|
| Subject
|
:
|
COMPUTERS-- General.
|
| Subject
|
:
|
Graphics processing units.
|
| Dewey Classification
|
:
|
006.6869
|
| LC Classification
|
:
|
T385.A243 2018
|
| Added Entry
|
:
|
Fung, Wilson Wai Lun
|
|
|
:
|
Rogers, Timothy G.
|