Zusammenfassung der Projektergebnisse

We have successfully shown the benefits of a system concept based on tightly integrated multi-grained reconfigurable tiles that is able to satisfy and improve execution performance compared to state-of-the-art approaches. This has been achieved by novel contributions in each of the three research areas that are closely related to each other. On the hardware side, a novel reconfigurable architecture on tile granularity has been realized. Different to state-of-the-art, the advantages of this architecture are the ease of high-level programmability as well as the possibility to realize highly optimized accelerators based on a common hardware substrate. The architecture is therefore composed out of tightly interconnected reconfigurable tiles. The microarchitecuture of these tiles has specifically been designed to meet different requirements: low hardware complexity, scalability to flexibly combine tiles to heterogeneous processor instances, efficient high-level programming support, high performance for both general purpose processors as well as accelerators, and small reconfiguration costs. Compliance with these objectives has been obtained by a careful analysis of general purpose processor as well as accelerator requirements for the definition of a common hardware substrate that both modes can share and a well defined co-design of complex tasks between hardware and compile time. As a result, our developed tile-based reconfigurable architecture supports resource-aware adaptation to diverse applications, support for different models of parallel programming, reduces programming complexity through support for smooth application improvement, reduces diversity of core architecture variants thus simplifying the hardware design process. For supporting the flexibility introduced by reconfiguration of the hardware architecture, a novel flexible Software Framework was necessary. The problem here is that dependent on the hardware configuration also the interface to the software, the Instruction Set Architecture (ISA), changes. Thus, a software framework that supports parallel code generation for multiple ISAs is required. The software framework consists of three components: A mixed-ISA compiler, mixed-ISA binary utilities, and a mixed-ISA simulator. All components are kept user-retargetable by a novel Architecture Description Language (ADL) including all supported ISAs as well as to enable design-space exploration and support for custom instructions. The developed KAHRISMA compiler features mixed-ISA software development by generating several ISA alternative of one function in one compilation run as well as supporting mixed-ISA application development that change their ISA/configuration at run time. The binary utilites support the mixed-ISA code generation on the assembler and linker level. The overall framework is evaluated by the mixed-ISA simulator that also supports the reconfiguration on instruction-level for the simulation. Our run-time system enables efficient simultaneous multi-tasking in reconfigurable processors with functional block level allocation of the multi-grained reconfigurable fabric while maintaining the application’s QoS requirement under run-time varying scenarios. Additionally, it provides a dynamic trade-off between performance and available area of multi-grained fabrics by selecting multi-grained instructions. Our Constraints-based Resource-Distributor adaptively allocates the fabric to different tasks considering their refined performance constraints and criticalities such that the number for deadline misses are reduced. The On-Demand Resource-Lender enables the situation dependent optimization by further utilizing the available configured EDPEs, which are temporarily not in use of the owner tasks. Compared to state-of-the-art, our scheme reduces the deadline misses by (on average) 3×, while improving the overall performance by 1.3×. Furthermore, our novel run-time system fully exploits the adaptivity provided by multi-grained ISEs by using intermediate ISEs and mono-CG extensions. We showed the applicability of our proposed run-time system on state-of-the-art processors like Morpheus, 4S, and RISPP and we showed the benefits that the KAHRISMA architecture provides.

Projektbezogene Publikationen (Auswahl)

• KAHRISMA: A novel Hypermorphic Reconfigurable-Instruction-Set Multi-grained-Array architecture. In Design, Automation & Test in Europe Conference & Exhibition (DATE), pages 819–824, March 2010
  R. Koenig, L. Bauer, T. Stripf, M. Shafique, W. Ahmed, J. Becker, and J. Henkel
  
• A novel ADL-based compiler-centric software framework for reconfigurable mixed-ISA processors. In International Conference on Embedded Computer Systems (SAMOS), pages 157–164, July 2011
  T. Stripf, R. Koenig, and J. Becker
  
• A scalable microarchitecture design that enables dynamic code execution for variable-issue clustered processors. In IEEE International Symposium on Parallel and Distributed Processing Workshops and Phd Forum (IPDPSW), pages 150–157, May 2011
  R. Koenig, T. Stripf, J. Heisswolf, and J. Becker
  
• Adaptive resource management for simultaneous multitasking in mixed-grained reconfigurable multi-core processors. In 9th International Conference on Hardware/Software Codesign and System Synthesis (CODES+ISSS), pages 365– 374, Oct. 2011
  W. Ahmed, M. Shafique, L. Bauer, and J. Henkel
  
• Architecture design space exploration of run-time scalable issue-width processors. In International Conference on Embedded Computer Systems (SAMOS), pages 77–84, July 2011
  R. Koenig, T. Stripf, J. Heisswolf, and J. Becker
  
• mRTS: Run-time system for reconfigurable processors with multi-grained instruction-set extensions. In Design, Automation & Test in Europe Conference & Exhibition (DATE), pages 1–6, March 2011
  W. Ahmed, M. Shafique, L. Bauer, and J. Henkel
  
• Run-time resource allocation for simultaneous multi-tasking in multi-core reconfigurable processors. In IEEE 19th Annual International Symposium on Field-Programmable Custom Computing Machines (FCCM), pages 29–32, May 2011
  W. Ahmed, M. Shafique, L. Bauer, M. Hammerich, J. Henkel, and J. Becker
  
• A compiler back-end for reconfigurable, mixed- ISA processors with clustered register files. In IEEE 26th International Parallel and Distributed Processing Symposium Workshops and PhD Forum (IPDPSW), pages 462–469, May 2012
  T. Stripf, R. Koenig, P. Rieder, and J. Becker
  
• A cycle-approximate, mixed-ISA simulator for the KAHRISMA architecture. In Design, Automation Test in Europe Conference Exhibition (DATE), pages 21–26, March 2012
  T. Stripf, R. Koenig, and J. Becker
  
• Grobgranular rekonfigurierbare Mikroarchitekturen zur dynamischen Erzeugung heterogener Prozessorinstanzen in Chip-Multiprozessoren. PhD thesis, Karlsruhe Institute of Technology, Institute for Information Processing Technologies, December 2012
  Ralf Koenig