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Cost-Effective Methodology for Complex Tuning Searches in HPC: Navigating Interdependencies and Dimensionality


核心概念
Our methodology adapts and refines traditional optimization methods to ensure computational feasibility while maximizing performance gains in real-world scenarios, particularly in High-Performance Computing (HPC) environments.
要約

Tuning searches are crucial in addressing complex optimization challenges in HPC applications. The content discusses the dilemma of conducting independent tuning searches for each routine or pursuing a more resource-intensive joint search due to potential interdependencies among parameters. The methodology presented efficiently explores the search space, leading to optimized configurations with reduced search time and increased accuracy. It also highlights the adaptability and efficiency of the approach beyond specific applications like Real-Time Time-Dependent Density Functional Theory (RT-TDDFT).

The content delves into Bayesian optimization as a popular method for exploring promising regions of the search space intelligently. It emphasizes the challenges posed by high dimensionality in tuning searches and the importance of analyzing interdependencies among parameters and routines. The methodology introduced aims to tackle these challenges by merging dependent searches when appropriate, resulting in an optimized set of searches with favorable results.

Furthermore, insights from sensitivity analysis, feature importance analysis, and Pearson correlation analysis provide valuable information on parameter variability, influence on runtimes, and interdependence between different routines within an application. The methodology guides the establishment of lower-dimensional searches based on these insights to optimize performance effectively.

Overall, the content offers a comprehensive exploration of cost-effective methodologies for complex tuning searches in HPC environments, showcasing practical applications and benefits across various scenarios.

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統計
Tested methodology suggested final configurations up to 8% more accurate with reduced search time by up to 95% Parameters influenced runtime variability significantly; nstb was most influential at 21.71% for Case Study 1 Sensitivity analysis revealed interdependence between Group 2 and Group 3 parameters impacting GPU kernels
引用
"The complexity arises not only from finely tuning parameters within routines but also potential interdependencies among them." "Our methodology leverages a cost-effective interdependence analysis to decide whether to merge several tuning searches into a joint search or conduct orthogonal searches."

抽出されたキーインサイト

by Adrian Perez... 場所 arxiv.org 03-14-2024

https://arxiv.org/pdf/2403.08131.pdf
Cost-Effective Methodology for Complex Tuning Searches in HPC

深掘り質問

How can the methodology be adapted for different types of HPC applications beyond RT-TDDFT?

The methodology outlined in the context can be adapted for various types of HPC applications by following a similar structured approach tailored to the specific characteristics of each application. Here are some key steps to adapt the methodology: Domain Knowledge and Complexity: Domain experts should define the optimal range of values for parameters based on the particular application, considering factors like computational resources, performance goals, and constraints. Insights about Parameters: Conduct sensitivity analysis to understand how variations in parameters impact runtime. This analysis helps identify influential parameters that significantly affect performance. Inferring Independent Routines: Use sensitivity analysis to infer interdependence between tuning routines within the application. Determine which routines exhibit strong interdependencies and need to be merged for joint tuning searches. Establishing the Set of Tuning Searches: Based on insights from sensitivity analysis and domain knowledge, decide whether to conduct independent or merged searches for different groups of parameters or routines within the application. Execution and Evaluation: Implement Bayesian optimization or other search mechanisms as per computing budget constraints, evaluate configurations iteratively, and refine search strategies based on results obtained during execution. By customizing these steps according to the specific requirements and characteristics of different HPC applications, this methodology can effectively optimize tuning searches across a wide range of computational domains beyond RT-TDDFT.

What are some potential drawbacks or limitations of merging dependent tuning searches?

While merging dependent tuning searches can offer several advantages in terms of efficiency and performance optimization, there are also potential drawbacks and limitations: Increased Complexity: Merging dependent searches may introduce additional complexity due to interdependencies among parameters or routines that need careful consideration during optimization. Higher Dimensionality: Combining multiple sets of parameters into a joint search increases dimensionality, which can lead to challenges in modeling complex relationships accurately with limited data points. Resource Intensive: Running joint searches for all dependent routines may require more computational resources compared to independent searches, especially when dealing with large-scale applications with numerous tunable parameters. Risk of Overfitting: There is a risk that merging dependent searches could result in overfitting if not properly controlled or if there is insufficient data available for accurate modeling. Limited Flexibility: Merged searches may limit flexibility in exploring diverse parameter combinations independently across different routines within an application.

How might advancements in GPU technology impact the effectiveness of this cost-effective methodology over time?

Advancements in GPU technology have significant implications for enhancing the effectiveness of cost-effective methodologies like Bayesian optimization applied to HPC applications: Increased Computational Power: More powerful GPUs enable faster computations and larger-scale simulations, allowing for more extensive exploration of parameter spaces within shorter timeframes. 2 .Improved Parallel Processing: Advancements such as increased parallel processing capabilities on GPUs enhance their ability to handle complex calculations efficiently. 3 .Enhanced Memory Bandwidth: Higher memory bandwidth on modern GPUs facilitates quicker data access speeds during computations, leading improvements overall system performance. 4 .Optimized Algorithms & Libraries - Continued development optimized algorithms specifically designed high-performance computing tasks further improve efficiency accuracy results generated through methodologies like Bayesian Optimization 5 .Reduced Training Time - Faster training times due improved hardware architecture allow models trained quickly , enabling rapid iteration refinement process Overall advancements GPU technology contribute towards faster , efficient , effective implementation cost-effective methodologies optimizing HPC Applications
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