Cyclades: Conflict-free Asynchronous Machine Learning

Xinghao Pan; Maximilian Lam; Stephen Tu; Dimitris Papailiopoulos; Ce Zhang; Kannan Ramchandran; Christopher Re; Michael I. Jordan; Michael I Jordan

2016 NIPS NeurIPS 2016

Cyclades: Conflict-free Asynchronous Machine Learning

Abstract

We present Cyclades, a general framework for parallelizing stochastic optimization algorithms in a shared memory setting. Cyclades is asynchronous during model updates, and requires no memory locking mechanisms, similar to Hogwild!-type algorithms. Unlike Hogwild!, Cyclades introduces no conflicts during parallel execution, and offers a black-box analysis for provable speedups across a large family of algorithms. Due to its inherent cache locality and conflict-free nature, our multi-core implementation of Cyclades consistently outperforms Hogwild!-type algorithms on sufficiently sparse datasets, leading to up to 40% speedup gains compared to Hogwild!, and up to 5\times gains over asynchronous implementations of variance reduction algorithms.

🌉 Interdisciplinary Bridge — Computer Science and Machine Learning and Mathematics & Optimization

📈 Trend Setter — Distributed Learning

🧭 Keyword Pioneer — conflict-free algorithm

🐣 Hot Topic Early Bird — convergence analysis

🐝 Cross-Pollinator — Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Interdisciplinary, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Robotics, Security & Privacy, Speech & Audio

Authors

Xinghao Pan , Maximilian Lam , Stephen Tu , Dimitris Papailiopoulos , Ce Zhang , Michael I. Jordan , Michael I Jordan , Kannan Ramchandran , Christopher Re

Topics

Machine Learning > Optimization & Theory > Distributed Learning Machine Learning > Optimization & Theory > Optimization Mathematics & Optimization > Optimization > Stochastic Methods Computer Science > Systems > Distributed Systems Machine Learning > Optimization & Theory > Stochastic Methods Machine Learning > Learning Types > Distributed Learning

Keywords

stochastic optimization convergence analysis parallel computing variance reduction parallel optimization shared memory asynchronous optimization asynchronous learning conflict-free algorithm parallel stochastic optimization conflict-free execution

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