Chrystian Guth scite author profile

Discrete gate sizing has attracted a lot of attention recently as the EDA industry faces the challenge of optimizing large standard cell-based circuits. The discrete nature of the problem, along with complex timing models, stringent design constraints, and ever-increasing circuit sizes, make the problem very difficult to tackle. Lagrangian Relaxation (LR) is an effective technique to handle complex constrained optimization problems and therefore has been successfully applied to solve the gate sizing problem. This article proposes an improved Lagrangian relaxation formulation for discrete gate sizing that relaxes timing, maximum gate input slew, and maximum gate output capacitance constraints. Based on such formulation, we propose a hybrid technique composed of three steps. First, a topological greedy heuristic solves the LR formulation. Such a heuristic is applied assuming a slightly increased target clock period (backoff factor) to better explore the solution space. Second, a delay recovery heuristic reestablishes the original target clock with small power overhead. Third, a power recovery heuristic explores the remaining slacks to further reduce power. Experiments on the ISPD 2012 Contest benchmarks show that our hybrid technique provides less leakage power than the state-of-the-art work for every circuit from the ISPD 2012 Contest infrastructure, achieving up to 24% less leakage. In addition, our technique achieves a much better compromise between leakage reduction and runtime, obtaining, on average, 9% less leakage power while running 8.8 times faster. ACM Reference Format: Vinicius S. Livramento, Chrystian Guth, José Luís Güntzel, and Marcelo O. Johann. 2014. A hybrid technique for discrete gate sizing based on lagrangian relaxation.

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Exploiting parallelism to speed up circuit legalization

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Guth

Livramento

et al. 2016

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Timing-Driven Placement Based on Dynamic Net-Weighting for Efficient Slack Histogram Compression

Guth

Livramento

Netto

et al. 2015

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Timing-driven placement (TDP) finds new legal locations for standard cells so as to minimize timing violations while preserving placement quality. Although violations may arise from unmet setup or hold constraints, most TDP approaches ignore the latter. Besides, most techniques focus on reducing the worst negative slack and let the improvements on total negative slack as a secondary goal. However, to successfully achieve timing closure, techniques must also reduce the total negative slack, which is known as slack histogram compression. This paper proposes a new Lagrangian Relaxation formulation for TDP to compress both late and early slack histograms. To solve the problem, we employ a discrete local search technique that uses the Lagrange multipliers as net-weights, which are dynamically updated using an accurate timing analyzer. To preserve placement quality, our technique uses a small fixed-size window that is anchored in the initial location of a cell. For the experimental evaluation of the proposed technique, we relied on the ICCAD 2014 TDP contest infrastructure. The results show that our technique significantly reduces the timing violations from an initial global placement. On average, late and early total negative slacks are improved by 85.03% and 42.72%, respectively, while the worst slacks are reduced by 71.55% and 34.40%. The overhead in wirelength is less than 0.1%.

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Chrystian Guth

Fast and Efficient Lagrangian Relaxation-Based Discrete Gate Sizing

Evaluating the impact of slew on delay and power of neighboring gates in discrete gate sizing

A Hybrid Technique for Discrete Gate Sizing Based on Lagrangian Relaxation

Exploiting parallelism to speed up circuit legalization

Timing-Driven Placement Based on Dynamic Net-Weighting for Efficient Slack Histogram Compression

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