doi: 10.3850/978-3-9815370-4-8_1114
Novel Inexact Memory Aware Algorithm Co-design for Energy Efficient Computation – Algorithmic Principles
Guru Prakash Arumugam1,a, Prashanth Srikanthan1,b, John Augustine1,c, Krishna Palem2,g, Eli Upfal3,h, Ayush Bhargava1,d, Parishkrati1,e and Sreelatha Yenugula1,f
1Department of Computer Science and Engineering
Indian Institute of Technology Madras
Chennai, India.
aguruprakash991@gmail.com
bprashanthxs@gmail.com
caugustine@cse.iitm.ac.in
dayush.bhargava15@gmail.com
eparishkratihhh@gmail.com
fsreelatha.yenugula@gmail.com
2Department of Computer Science
Rice University, Houston, USA.
gkvp1@rice.edu
3Department of Computer Science
Brown University
Providence, RI, USA.
heli@cs.brown.edu
ABSTRACT
It is increasingly accepted that energy savings can be
achieved by trading the accuracy of a computing system for energy
gains–quite often significantly. This approach is referred to as
inexact or approximate computing. Given that a significant portion
of the energy in a modern general purpose processor is spent on
moving data to and from storage, and that increasingly data
movement contributes significantly to activity during the execution
of applications, it is important to be able to develop techniques and
methodologies for inexact computing in this context. To accomplish
this to its fullest level, it is important to start with algorithmic
specifications and alter their intrinsic design to take advantage of
inexactness. This calls for a new approach to inexact memory
aware algorithm design (IMAD) or co-design. In this paper, we
provide the theoretical foundations which include novel models as
well as technical results in the form of upper and lower bounds for
IMAD in the context of universally understood and canonical
problems: variations of sorting, and string matching. Surprisingly,
IMAD allowed us to design entirely error-free algorithms while
achieving energy gain factors of 1.5 and 5 in the context of sorting
and string matching when compared to their traditional (textbook)
algorithms. IMAD is also amenable to theoretical analysis and we
present several asymptotic bounds on energy gains.
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