Swarm Intelligence Driven Simultaneous Adaptive Exploration of Datapath and Loop Unrolling Factor during Area-Performance Tradeoff

Multi objective (MO) design space exploration (DSE) in high level synthesis (HLS) is a tedious task which administers the usage of intelligent decision making strategies at multiple stages to yield quality results. The problem of DSE becomes intractable and intricate when an auxiliary variable such...

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Bibliographic Details
Main Authors: Sengupta, Anirban, Mishra, Vipul Kumar
Format: Conference Proceeding
Language:English
Subjects:
adaptive
Algorithm design and analysis
automated
Cascading style sheets
Delays
Gold
Multiplexing
Particle swarm optimization
Space exploration
swarm
Unrolling factor
Online Access:Request full text
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Summary:Multi objective (MO) design space exploration (DSE) in high level synthesis (HLS) is a tedious task which administers the usage of intelligent decision making strategies at multiple stages to yield quality results. The problem of DSE becomes intractable and intricate when an auxiliary variable such as loop unrolling factor plays a vital role in the decision making process. This paper successfully solves the above problem by proposing the novel DSE approach for fully automated parallel (simultaneous) exploration of optimal datapath and unrolling factor (UF) during area-performance tradeoff in HLS. The proposed DSE approach is driven by hyper-dimensional particle swarm optimization (PSO). The major sub-contributions of this proposed algorithm includes: a) deriving a model for computation of execution delay of a loop unrolled control data flow graph (CDFG) based on resource constraint, without the necessity of tediously unrolling the entire CDFG in most cases, b) Consideration of loop unrolling and its impact on: i) control states and execution delay tradeoff during loop unrolling ii) area-execution delay tradeoff during the DSE process, c) novel comparative results for area-performance tradeoff with respect to multiple DFG and CDFG benchmarks. Results of the proposed approach indicated an average improvement in Quality of Results (QoR) of > 30% and reduction in runtime of > 92% compared to recent approaches.
ISSN:2159-3469
2159-3477
DOI:10.1109/ISVLSI.2014.10