A general interprocedural framework for placement of split-phase large latency operations

Gagan Agrawal

doi:10.1109/71.762818

A general interprocedural framework for placement of split-phase large latency operations

Gagan Agrawal

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

Overlapping split-phase large latency operations with computations is a standard technique for improving performance on modern architectures. In this paper, we present a general interprocedural technique for overlapping such accesses with computation. We have developed an Interprocedural Balanced Code Placement (IBCP) framework, which performs analysis on arbitrary recursive procedures and arbitrary control flow and replaces synchronous operations with a balanced pair of asynchronous operations. We have evaluated this scheme in the context of overlapping I/O operations with computation. We demonstrate how this analysis is useful for applications which perform frequent and large accesses to disks, including applications which snapshot or checkpoint their computations or out-of-core applications.

Original language	English (US)
Pages (from-to)	394-413
Number of pages	20
Journal	IEEE Transactions on Parallel and Distributed Systems
Volume	10
Issue number	4
DOIs	https://doi.org/10.1109/71.762818
State	Published - 1999
Externally published	Yes

Keywords

Code motion
Data-flow analysis
Input/output
Interprocedural analysis
Memory hierarchy transformations

ASJC Scopus subject areas

Signal Processing
Hardware and Architecture
Computational Theory and Mathematics

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10.1109/71.762818

Cite this

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title = "A general interprocedural framework for placement of split-phase large latency operations",

abstract = "Overlapping split-phase large latency operations with computations is a standard technique for improving performance on modern architectures. In this paper, we present a general interprocedural technique for overlapping such accesses with computation. We have developed an Interprocedural Balanced Code Placement (IBCP) framework, which performs analysis on arbitrary recursive procedures and arbitrary control flow and replaces synchronous operations with a balanced pair of asynchronous operations. We have evaluated this scheme in the context of overlapping I/O operations with computation. We demonstrate how this analysis is useful for applications which perform frequent and large accesses to disks, including applications which snapshot or checkpoint their computations or out-of-core applications.",

keywords = "Code motion, Data-flow analysis, Input/output, Interprocedural analysis, Memory hierarchy transformations",

author = "Gagan Agrawal",

note = "Funding Information: We are grateful to Joel Saltz for his support of this research and to Anurag Acharya for suggesting the bechmarks for our experiments. We have implemented our source-to-source compiler using the Parascope/D System Fortran front end. We gratefully acknowledge our debt to its implementers. We would like to thank Bongki Moon for the dscm-3d program. We would also like to thank Tonjua Hines and Steve Kempler from the Earth Science Data & Information Systems Project (ESDIS) at NASA Goddard Space Flight Center for invaluable discussions about NASA's satellite data processing requirements and for helping us gain access to NASA programs. This research was supported in part by U.S. National Science Foundation (NSF) CAREER award ACI-9733520 and NSF grant CCR-9808522.",

year = "1999",

doi = "10.1109/71.762818",

language = "English (US)",

volume = "10",

pages = "394--413",

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AU - Agrawal, Gagan

N1 - Funding Information: We are grateful to Joel Saltz for his support of this research and to Anurag Acharya for suggesting the bechmarks for our experiments. We have implemented our source-to-source compiler using the Parascope/D System Fortran front end. We gratefully acknowledge our debt to its implementers. We would like to thank Bongki Moon for the dscm-3d program. We would also like to thank Tonjua Hines and Steve Kempler from the Earth Science Data & Information Systems Project (ESDIS) at NASA Goddard Space Flight Center for invaluable discussions about NASA's satellite data processing requirements and for helping us gain access to NASA programs. This research was supported in part by U.S. National Science Foundation (NSF) CAREER award ACI-9733520 and NSF grant CCR-9808522.

PY - 1999

Y1 - 1999

N2 - Overlapping split-phase large latency operations with computations is a standard technique for improving performance on modern architectures. In this paper, we present a general interprocedural technique for overlapping such accesses with computation. We have developed an Interprocedural Balanced Code Placement (IBCP) framework, which performs analysis on arbitrary recursive procedures and arbitrary control flow and replaces synchronous operations with a balanced pair of asynchronous operations. We have evaluated this scheme in the context of overlapping I/O operations with computation. We demonstrate how this analysis is useful for applications which perform frequent and large accesses to disks, including applications which snapshot or checkpoint their computations or out-of-core applications.

AB - Overlapping split-phase large latency operations with computations is a standard technique for improving performance on modern architectures. In this paper, we present a general interprocedural technique for overlapping such accesses with computation. We have developed an Interprocedural Balanced Code Placement (IBCP) framework, which performs analysis on arbitrary recursive procedures and arbitrary control flow and replaces synchronous operations with a balanced pair of asynchronous operations. We have evaluated this scheme in the context of overlapping I/O operations with computation. We demonstrate how this analysis is useful for applications which perform frequent and large accesses to disks, including applications which snapshot or checkpoint their computations or out-of-core applications.

KW - Code motion

KW - Data-flow analysis

KW - Input/output

KW - Interprocedural analysis

KW - Memory hierarchy transformations

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A general interprocedural framework for placement of split-phase large latency operations

Abstract

Keywords

ASJC Scopus subject areas

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