GPU-accelerated data management under the test of time

Anastasia Ailamaki, Angelos Christos Anadiotis, Periklis Chrysogelos, Syed Mohammad Aunn Raza, Panagiotis Sioulas
2020
Article de conférence

Résumé

GPUs are becoming increasingly popular in large scale data center installations due to their strong, embarrassingly parallel, processing capabilities. Data management systems are riding the wave by using GPUs to accelerate query execution, mainly for analytical workloads. However, this acceleration comes at the price of a slow interconnect which imposes strong restrictions in bandwidth and latency when bringing data from the main memory to the GPU for processing. The related research in data management systems mostly relies on late materialization and data sharing to mitigate the overheads introduced by slow interconnects even in the standard CPU processing case. Finally, workload trends move beyond analytical to fresh data processing, typically referred to as Hybrid Transactional and Analytical Processing (HTAP). Therefore, we experience an evolution in three different axes: interconnect technology, GPU architecture, and workload characteristics. In this paper, we break the evolution of the technological landscape into steps and we study the applicability and performance of late materialization and data sharing in each one of them. We demonstrate that the standard PCIe interconnect substantially limits the performance of state-of-the-art GPUs and we propose a hybrid materialization approach which combines eager with lazy data transfers. Further, we show that the wide gap between GPU and PCIe throughput can be bridged through efficient data sharing techniques. Finally, we provide an H2TAP system design which removes software-level interference and we show that the interference in the memory bus is minimal, allowing data transfer optimizations as in OLAP workloads.

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https://infoscience.epfl.ch/record/277001?ln=fr

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Anastasia Ailamaki, Angelos Christos Anadiotis, Periklis Chrysogelos, Syed Mohammad Aunn Raza, Panagiotis Sioulas
2020
Article de conférence

Résumé

Official source

https://infoscience.epfl.ch/record/277001?ln=fr

À propos de ce résultat

Concepts associés (14)

Concepts associés

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Publications associées (14)

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Publications associées

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Publications associées (14)

Database workloads have significantly evolved in the past twenty years. Traditional database systems that are mainly used to serve Online Transactional Processing (OLTP) workloads evolved into specialized database systems that are optimized for particular types of workloads. Data warehousing applications have led to Online Analytical Processing (OLAP) workloads and real-time analytical processing applications have led to Hybrid Transactional and Analytical Processing (HTAP) workloads. Similarly, modern hardware has significantly evolved in the past twenty years. Unicore, simple processors with megabytes of main memory have evolved into multi-core, power-limited processors with hundreds of gigabytes of main memory. Furthermore, the processors have complex micro-architectural features such as Single Instruction Multiple Data (SIMD) instructions and complex branch predictors. Advancements in processor technology have led to further evolution of database systems with novel system architectures and query processing paradigms. We present the micro-architectural behavior of modern database workloads on a modern processor for various categories of workloads and generations of database systems. We examine three main categories of database workloads and study them separately: OLTP, OLAP, and HTAP. We show that OLTP systems spend most of their execution time waiting for instruction-cache or data-cache misses, where the data-cache misses are due to the random data-accesses during the index lookup operation. While using an efficient index structure can significantly reduce the number of data-cache misses, the main micro-architectural bottleneck remains the data-cache misses due to the costly random data-accesses. Hence, OLTP systems should adopt techniques that mitigate the random data-accesses. OLAP systems spend most of their execution time in data-cache misses, where the data-cache misses are due to high pressure on the memory bandwidth for sequential-scan-heavy queries, and are due to random data-accesses for join-intensive queries. OLAP systems that follow tuple-at-a-time execution models efficiently use the CPU cycles. However, they require executing a significantly larger number of instructions hence are significantly slower than the systems that follow vector-at-a-time and compiled execution models. Therefore, OLAP systems should use efficient execution models and adopt techniques that mitigate data-cache misses. HTAP systems combine OLTP and OLAP systems into a single, unified system, where the OLTP and OLAP systems run on the same hardware and on the same data. Running on the same hardware results in hardware-level interference, where the OLTP throughput significantly drops due to the OLAP side sharing the hardware resources. Running on the same data results in increased OLAP query execution time due to the need for the OLAP side to process the fresh tuples generated by the OLTP side. Therefore, HTAP systems should adopt techniques that mitigate the hardware-level interference and should make sure that the OLAP side uses enough resources to minimize the increased query execution time.

EPFL2021

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Efficient Analytical Query Processing on CPU-GPU Hardware Platforms

Periklis Chrysogelos

Timely insights lead to business growth and scientific breakthroughs but require analytical engines that cope with the ever-increasing data processing needs. Analytical engines relied on rapid CPU improvements, yet the end of Dennard scaling stopped the free lunch and resulted in a heterogeneous hardware landscape that challenges existing analytical engines. First, each device has its own specialized execution model and architecture, impeding interoperability. Second, the diversity in device microarchitectures requires a diverse range of optimizations. Third, while the multitude of devices provides additional acceleration opportunities, moving the data across devices is costly. Finally, with networking bandwidths similar to intra-server device connections, the server boundaries are blurred, providing optimization opportunities and requiring careful orchestration to avoid wasting resources. In this thesis, we aim for engines tailored for heterogeneous hardware: abstracting out hardware heterogeneity to enable efficient execution across the devices despite their diversity. To this end, we design and implement techniques that are i) scalable through accelerator-level parallelism, and ii) efficient through query execution customization to the underlying accelerators and data transfer paths.Regarding scalability, we propose a unifying execution model and a throughput-oriented system view to enable on-the-fly multi-device orchestration without requiring knowledge about hardware specifics. In addition, by decoupling data and control flow, this thesis enables late and direct data transfers within and across servers.Regarding efficiency, we provide an execution model that limits operator instances to specific devices, enabling operators to customize themselves to a single device without concern for multi-device effects. In addition, by providing interconnect-aware transfer methods, this thesis minimizes the cost of offloading operations across devices.This thesis redesigns analytical engines to exploit hardware heterogeneity. Instead of trading hardware efficiency for accelerator-level scalability, this thesis embraces heterogeneity. Our design enables scalable analytics across CPU-GPU hardware and achieves the analytical performance of optimally combining a CPU- and a GPU-optimized engine. As a result, users benefit from faster insights without requiring large clusters of machines. The proposed accelerator-centric design paves the way toward analytical engines that benefit from hardware improvements across the hardware spectrum -- instead of relying on single-processor advancements.

EPFL2022

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Scaling up analytical queries with column-stores

Anastasia Ailamaki, Ioannis Alagiannis, Manoussos Gavriil Athanassoulis

As data analytics is used by an increasing number of applications, data analytics engines are required to execute workloads with increased concurrency, i.e., an increasing number of clients submitting queries. Data management systems designed for data analytics - a market dominated by column-stores - however, were initially optimized for single query execution, minimizing its response time. Hence, they do not treat concurrency as a first class citizen. In this paper, we experiment with one open-source and two commercial column-stores using the TPC-H and SSB benchmarks in a setup with an increasing number of concurrent clients submitting queries, focusing on whether the tested systems can scale up in a single node instance. The tested systems for in-memory workloads scale up, to some degree; however, when the server is saturated they fail to fully exploit the available parallelism. Further, we highlight the unpredictable response times for high concurrency.

2013

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Efficient Analytical Query Processing on CPU-GPU Hardware Platforms

Periklis Chrysogelos

EPFL2022

EPFL2021