Modern High-Performance Computing (HPC) systems are adding extra layers to the memory and storage hierarchy named deep memory and storage hierarchy (DMSH), to increase I/O performance. New hardware technologies, such as NVMe and SSD, have been introduced in burst buffer installations to reduce the pressure for external storage and boost the burstiness of modern I/O systems. The DMSH has demonstrated its strength and potential in practice. However, each layer of DMSH is an independent heterogeneous system and data movement among more layers is significantly more complex even without considering heterogeneity. How to efficiently utilize the DMSH is a subject of research facing the HPC community. In this paper, we present the design and implementation of Hermes: a new, heterogeneous-aware, multi-tiered, dynamic, and distributed I/O buffering system. Hermes enables, manages, supervises, and, in some sense, extends I/O buffering to fully integrate into the DMSH. We introduce three novel data placement policies to efficiently utilize all layers and we present three novel techniques to perform memory, metadata, and communication management in hierarchical buffering systems. Our evaluation shows that, in addition to automatic data movement through the hierarchy, Hermes can significantly accelerate I/O and outperforms by more than 2x state-of-the-art buffering platforms.

https://dl.acm.org/doi/pdf/10.1145/3208040.3208059

Hermes: a heterogeneous-aware multi-tiered distributed I/O buffering system

Modern HPC systems employ burst buffer installations to reduce the peak I/O requirements for external storage and deal with the burstiness of I/O in modern scientific applications. These I/O buffering resources are shared between multiple applications that run concurrently. This leads to severe performance degradation due to contention, a phenomenon called cross-application I/O interference. In this paper, we first explore the negative effects of interference at the burst buffer layer and we present two new metrics that can quantitatively describe the slowdown applications experience due to interference. We introduce Harmonia, a new dynamic I/O scheduler that is aware of interference, adapts to the underlying system, implements a new 2-way decision-making process and employs several scheduling policies to maximize the system efficiency and applications' performance. Our evaluation shows that Harmonia, through better I/O scheduling, can outperform by 3x existing state-of-the-art buffering management solutions and can lead to better resource utilization.

Harmonia: An Interference-Aware Dynamic I/O Scheduler for Shared Non-volatile Burst Buffers

This paper offers a solution to overcome the complexities of production system I/O performance monitoring. We present Beacon, an end-to-end I/O resource monitoring and diagnosis system for the 40960-node Sunway TaihuLight supercomputer, currently the fourth-ranked supercomputer in the world. Beacon simultaneously collects and correlates I/O tracing/profiling data from all the compute nodes, forwarding nodes, storage nodes, and metadata servers. With mechanisms such as aggressive online and offline trace compression and distributed caching/storage, it delivers scalable, low-overhead, and sustainable I/O diagnosis under production use. With Beacon’s deployment on TaihuLight for more than three years, we demonstrate Beacon’s effectiveness with real-world use cases for I/O performance issue identification and diagnosis. It has already successfully helped center administrators identify obscure design or configuration flaws, system anomaly occurrences, I/O performance interference, and resource under- or over-provisioning problems. Several of the exposed problems have already been fixed, with others being currently addressed. Encouraged by Beacon’s success in I/O monitoring, we extend it to monitor interconnection networks, which is another contention point on supercomputers. In addition, we demonstrate Beacon’s generality by extending it to other supercomputers. Both Beacon codes and part of collected monitoring data are released.1

/pdf/end-to-end-i-o-monitoring-on-leading-supercomputers-24ck8api.pdf

End-to-end I/O Monitoring on Leading Supercomputers

Many scientific fields increasingly use high-performance computing (HPC) to process and analyze massive amounts of experimental data while storage systems in today’s HPC environments have to cope with new access patterns. These patterns include many metadata operations, small I/O requests, or randomized file I/O, while general-purpose parallel file systems have been optimized for sequential shared access to large files. Burst buffer file systems create a separate file system that applications can use to store temporary data. They aggregate node-local storage available within the compute nodes or use dedicated SSD clusters and offer a peak bandwidth higher than that of the backend parallel file system without interfering with it. However, burst buffer file systems typically offer many features that a scientific application, running in isolation for a limited amount of time, does not require. We present GekkoFS, a temporary, highly-scalable file system which has been specifically optimized for the aforementioned use cases. GekkoFS provides relaxed POSIX semantics which only offers features which are actually required by most (not all) applications. GekkoFS is, therefore, able to provide scalable I/O performance and reaches millions of metadata operations already for a small number of nodes, significantly outperforming the capabilities of common parallel file systems.

/pdf/gekkofs-a-temporary-burst-buffer-file-system-for-hpc-3fubsj5gvs.pdf

GekkoFS — A Temporary Burst Buffer File System for HPC Applications

Storage backends of parallel compute clusters are still based mostly on magnetic disks, while newer and faster storage technologies such as flash-based SSDs or non-volatile random access memory (NVRAM) are deployed within compute nodes. Including these new storage technologies into scientific workflows is unfortunately today a mostly manual task, and most scientists therefore do not take advantage of the faster storage media. One approach to systematically include nodelocal SSDs or NVRAMs into scientific workflows is to deploy ad hoc file systems over a set of compute nodes, which serve as temporary storage systems for single applications or longer-running campaigns. This paper presents results from the Dagstuhl Seminar 17202 “Challenges and Opportunities of User-Level File Systems for HPC” and discusses application scenarios as well as design strategies for ad hoc file systems using node-local storage media. The discussion includes open research questions, such as how to couple ad hoc file systems with the batch scheduling environment and how to schedule stage-in and stage-out processes of data between the storage backend and the ad hoc file systems. Also presented are strategies to build ad hoc file systems by using reusable components for networking and how to improve storage device compatibility. Various interfaces and semantics are presented, for example those used by the three ad hoc file systems BeeOND, GekkoFS, and BurstFS. Their presentation covers a range from file systems running in production to cutting-edge research focusing on reaching the performance limits of the underlying devices.

/pdf/ad-hoc-file-systems-for-high-performance-computing-4ir8qt1imb.pdf

Ad hoc file systems for high-performance computing

Modern scientific applications read and write massive amounts of data through simulations, observations, and analysis. These applications spend the majority of their runtime in performing I/O. HPC storage solutions include fast node-local and shared storage resources to elevate applications from this bottleneck. Moreover, several middleware libraries (e.g., Hermes) are proposed to move data between these tiers transparently. Data reduction is another technique that reduces the amount of data produced and, hence, improve I/O performance. These two technologies, if used together, can benefit from each other. The effectiveness of data compression can be enhanced by selecting different compression algorithms according to the characteristics of the different tiers, and the multi-tiered hierarchy can benefit from extra capacity. In this paper, we design and implement HCompress, a hierarchical data compression library that can improve the application’s performance by harmoniously leveraging both multi-tiered storage and data compression. We have developed a novel compression selection algorithm that facilitates the optimal matching of compression libraries to the tiered storage. Our evaluation shows that HCompress can improve scientific application’s performance by 7x when compared to other state-of-the-art tiered storage solutions.

HCompress: Hierarchical Data Compression for Multi-Tiered Storage Environments

In the era of data-intensive computing, accessing data with a high-throughput and low-latency is more imperative than ever. Data prefetching is a well-known technique for hiding read latency. However, existing solutions do not consider the new deep memory and storage hierarchy and also suffer from under-utilization of prefetching resources and unnecessary evictions. Additionally, existing approaches implement a client-pull model where understanding the application’s I/O behavior drives prefetching decisions. Moving towards exascale, where machines run multiple applications concurrently by accessing files in a workflow, a more data-centric approach can resolve challenges such as cache pollution and redundancy. In this study, we present HFetch, a truly hierarchical data prefetcher that adopts a server-push approach to data prefetching. We demonstrate the benefits of such an approach. Results show 10-35% performance gains over existing prefetchers and over 50% when compared to systems with no prefetching.

HFetch: Hierarchical Data Prefetching for Scientific Workflows in Multi-Tiered Storage Environments

The data explosion phenomenon in modern applications causes tremendous stress on storage systems. Developers use data compression, a size-reduction technique, to address this issue. However, each compression library exhibits different strengths and weaknesses when considering the input data type and format. We present Ares, an intelligent, adaptive, and flexible compression framework which can dynamically choose a compression library for a given input data based on the type of the workload and provides an appropriate infrastructure to users to fine-tune the chosen library. Ares is a modular framework which unifies several compression libraries while allowing the addition of more compression libraries by the user. Ares is a unified compression engine that abstracts the complexity of using different compression libraries for each workload. Evaluation results show that under real-world applications, from both scientific and Cloud domains, Ares performed 2-6x faster than competitive solutions with a low cost of additional data analysis (i.e., overheads around 10%) and up to 10x faster against a baseline of no compression at all.

An Intelligent, Adaptive, and Flexible Data Compression Framework

Modern High-Performance Computing (HPC) systems are adding extra layers to the memory and storage hierarchy, named deep memory and storage hierarchy (DMSH), to increase I/O performance. New hardware technologies, such as NVMe and SSD, have been introduced in burst buffer installations to reduce the pressure for external storage and boost the burstiness of modern I/O systems. The DMSH has demonstrated its strength and potential in practice. However, each layer of DMSH is an independent heterogeneous system and data movement among more layers is significantly more complex even without considering heterogeneity. How to efficiently utilize the DMSH is a subject of research facing the HPC community. Further, accessing data with a high-throughput and low-latency is more imperative than ever. Data prefetching is a well-known technique for hiding read latency by requesting data before it is needed to move it from a high-latency medium (e.g., disk) to a low-latency one (e.g., main memory). However, existing solutions do not consider the new deep memory and storage hierarchy and also suffer from under-utilization of prefetching resources and unnecessary evictions. Additionally, existing approaches implement a client-pull model where understanding the application’s I/O behavior drives prefetching decisions. Moving towards exascale, where machines run multiple applications concurrently by accessing files in a workflow, a more data-centric approach resolves challenges such as cache pollution and redundancy. In this paper, we present the design and implementation of Hermes: a new, heterogeneous-aware, multi-tiered, dynamic, and distributed I/O buffering system. Hermes enables, manages, supervises, and, in some sense, extends I/O buffering to fully integrate into the DMSH. We introduce three novel data placement policies to efficiently utilize all layers and we present three novel techniques to perform memory, metadata, and communication management in hierarchical buffering systems. Additionally, we demonstrate the benefits of a truly hierarchical data prefetcher that adopts a server-push approach to data prefetching. Our evaluation shows that, in addition to automatic data movement through the hierarchy, Hermes can significantly accelerate I/O and outperforms by more than 2x state-of-the-art buffering platforms. Lastly, results show 10%–35% performance gains over existing prefetchers and over 50% when compared to systems with no prefetching.

Anthony Kougkas

Papers

Harmonia: An Interference-Aware Dynamic I/O Scheduler for Shared Non-volatile Burst Buffers

HCompress: Hierarchical Data Compression for Multi-Tiered Storage Environments

HFetch: Hierarchical Data Prefetching for Scientific Workflows in Multi-Tiered Storage Environments

An Intelligent, Adaptive, and Flexible Data Compression Framework

I/O Acceleration via Multi-Tiered Data Buffering and Prefetching