A distributed processor state management architecture for large-window processors

Isidro González; Marco Galluzzi; Alex Veidenbaum; Marco A. Ramírez; Adrián Cristal; Mateo Valero

doi:10.1109/MICRO.2008.4771775

A distributed processor state management architecture for large-window processors

Isidro González, Marco Galluzzi, Alex Veidenbaum, Marco A. Ramírez, Adrián Cristal, Mateo Valero

Centro de Investigación en Computación (CIC)

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

6 Scopus citations

Abstract

Processor architectures with large instruction windows have been proposed to expose more instruction-level parallelism (ILP) and increase performance. Some of the proposed architectures replace a re-order buffer (ROB) with a checkpointing mechanism and an out-of-order release of processor resources. Check-pointing, however, leads to an imprecise processor state recovery on mis-predicted branches and exceptions and re-execution of correct-path instructions after state recovery. It also requires large register files complicating renaming, allocation and release of physical registers. This paper proposes a new processor architecture called a Multi-State Processor (MSP). The MSP does not use check-pointing, avoids the above-mentioned problems, and has a fast, distributed state recovery mechanism. The MSP uses a novel register management architecture allowing implementation of large register files with simpler and more scalable register allocation, renaming, and release. It is also key to precise processor state recovery mechanism. The MSP is shown to improve IPC by 14%, on average, for integer SPEC CPU2000 benchmarks compared to a check-pointing based mechanism ([2]) when a fast and simple branch predictor is used. With a very aggressive branch predictor the IPC improvement is 1%, on average, and 3% if some of the programs are optimized for the MSP. The MSP also reduces the average number of executed instructions by 16.5% (12% for the aggressive branch predictor), mostly due to precise state recovery. This improves the MSP processor energy efficiency even though it uses a larger register file.

Original language	English
Title of host publication	2008 Proceedings of the 41st Annual IEEE/ACM International Symposium on Microarchitecture, MICRO-41
Pages	11-22
Number of pages	12
Edition	2008 PROCEEDINGS
DOIs	https://doi.org/10.1109/MICRO.2008.4771775
State	Published - 2008
Event	2008 - 41st Annual IEEE/ACM International Symposium on Microarchitecture, MICRO-41 - Lake Como, Italy Duration: 8 Nov 2008 → 12 Nov 2008

Publication series

Name	Proceedings of the Annual International Symposium on Microarchitecture, MICRO
Number	2008 PROCEEDINGS
ISSN (Print)	1072-4451

Conference

Conference	2008 - 41st Annual IEEE/ACM International Symposium on Microarchitecture, MICRO-41
Country/Territory	Italy
City	Lake Como
Period	8/11/08 → 12/11/08

Keywords

Check-pointing
Component
Large-window
Misprediction recovery
Register file
Register renaming

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1109/MICRO.2008.4771775

Cite this

González, I., Galluzzi, M., Veidenbaum, A., Ramírez, M. A., Cristal, A., & Valero, M. (2008). A distributed processor state management architecture for large-window processors. In 2008 Proceedings of the 41st Annual IEEE/ACM International Symposium on Microarchitecture, MICRO-41 (2008 PROCEEDINGS ed., pp. 11-22). Article 4771775 (Proceedings of the Annual International Symposium on Microarchitecture, MICRO; No. 2008 PROCEEDINGS). https://doi.org/10.1109/MICRO.2008.4771775

González, Isidro ; Galluzzi, Marco ; Veidenbaum, Alex et al. / A distributed processor state management architecture for large-window processors. 2008 Proceedings of the 41st Annual IEEE/ACM International Symposium on Microarchitecture, MICRO-41. 2008 PROCEEDINGS. ed. 2008. pp. 11-22 (Proceedings of the Annual International Symposium on Microarchitecture, MICRO; 2008 PROCEEDINGS).

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abstract = "Processor architectures with large instruction windows have been proposed to expose more instruction-level parallelism (ILP) and increase performance. Some of the proposed architectures replace a re-order buffer (ROB) with a checkpointing mechanism and an out-of-order release of processor resources. Check-pointing, however, leads to an imprecise processor state recovery on mis-predicted branches and exceptions and re-execution of correct-path instructions after state recovery. It also requires large register files complicating renaming, allocation and release of physical registers. This paper proposes a new processor architecture called a Multi-State Processor (MSP). The MSP does not use check-pointing, avoids the above-mentioned problems, and has a fast, distributed state recovery mechanism. The MSP uses a novel register management architecture allowing implementation of large register files with simpler and more scalable register allocation, renaming, and release. It is also key to precise processor state recovery mechanism. The MSP is shown to improve IPC by 14%, on average, for integer SPEC CPU2000 benchmarks compared to a check-pointing based mechanism ([2]) when a fast and simple branch predictor is used. With a very aggressive branch predictor the IPC improvement is 1%, on average, and 3% if some of the programs are optimized for the MSP. The MSP also reduces the average number of executed instructions by 16.5% (12% for the aggressive branch predictor), mostly due to precise state recovery. This improves the MSP processor energy efficiency even though it uses a larger register file.",

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González, I, Galluzzi, M, Veidenbaum, A, Ramírez, MA, Cristal, A & Valero, M 2008, A distributed processor state management architecture for large-window processors. in 2008 Proceedings of the 41st Annual IEEE/ACM International Symposium on Microarchitecture, MICRO-41. 2008 PROCEEDINGS edn, 4771775, Proceedings of the Annual International Symposium on Microarchitecture, MICRO, no. 2008 PROCEEDINGS, pp. 11-22, 2008 - 41st Annual IEEE/ACM International Symposium on Microarchitecture, MICRO-41, Lake Como, Italy, 8/11/08. https://doi.org/10.1109/MICRO.2008.4771775

A distributed processor state management architecture for large-window processors. / González, Isidro; Galluzzi, Marco; Veidenbaum, Alex et al.
2008 Proceedings of the 41st Annual IEEE/ACM International Symposium on Microarchitecture, MICRO-41. 2008 PROCEEDINGS. ed. 2008. p. 11-22 4771775 (Proceedings of the Annual International Symposium on Microarchitecture, MICRO; No. 2008 PROCEEDINGS).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Galluzzi, Marco

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AU - Ramírez, Marco A.

AU - Cristal, Adrián

AU - Valero, Mateo

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AB - Processor architectures with large instruction windows have been proposed to expose more instruction-level parallelism (ILP) and increase performance. Some of the proposed architectures replace a re-order buffer (ROB) with a checkpointing mechanism and an out-of-order release of processor resources. Check-pointing, however, leads to an imprecise processor state recovery on mis-predicted branches and exceptions and re-execution of correct-path instructions after state recovery. It also requires large register files complicating renaming, allocation and release of physical registers. This paper proposes a new processor architecture called a Multi-State Processor (MSP). The MSP does not use check-pointing, avoids the above-mentioned problems, and has a fast, distributed state recovery mechanism. The MSP uses a novel register management architecture allowing implementation of large register files with simpler and more scalable register allocation, renaming, and release. It is also key to precise processor state recovery mechanism. The MSP is shown to improve IPC by 14%, on average, for integer SPEC CPU2000 benchmarks compared to a check-pointing based mechanism ([2]) when a fast and simple branch predictor is used. With a very aggressive branch predictor the IPC improvement is 1%, on average, and 3% if some of the programs are optimized for the MSP. The MSP also reduces the average number of executed instructions by 16.5% (12% for the aggressive branch predictor), mostly due to precise state recovery. This improves the MSP processor energy efficiency even though it uses a larger register file.

KW - Check-pointing

KW - Component

KW - Large-window

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KW - Register file

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González I, Galluzzi M, Veidenbaum A, Ramírez MA, Cristal A, Valero M. A distributed processor state management architecture for large-window processors. In 2008 Proceedings of the 41st Annual IEEE/ACM International Symposium on Microarchitecture, MICRO-41. 2008 PROCEEDINGS ed. 2008. p. 11-22. 4771775. (Proceedings of the Annual International Symposium on Microarchitecture, MICRO; 2008 PROCEEDINGS). doi: 10.1109/MICRO.2008.4771775

A distributed processor state management architecture for large-window processors

Abstract

Publication series

Conference

Keywords

UN SDGs

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