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Analysis of parallel scan processing in Shared Disk database systemsRahm, Erhard, Stöhr, Thomas 23 October 2018 (has links)
Shared Disk database systems offer a high flexibility for parallel transaction and query processing. This is because each node can process any transaction, query or subquery because it has access to the entire database. Compared to Shared Nothing database systems, this is particularly advantageous for scan queries for which the degree of intra-query parallelism as well as the scan processors themselves can dynamically be chosen. On the other hand, there is the danger of disk contention between subqueries, in particular for index scans. We present a detailed simulation study to analyze the effectiveness of parallel scan processing in Shared Disk database systems. In particular, we investigate the relationship between the degree of declustering and the degree of scan parallelism for relation scans, clustered index scans, and non-clustered index scans. Furthermore, we study the usefulness of disk caches and prefetching for limiting disk contention. Finally, we show that disk contention in multi-user mode can be limited for Shared Disk database systems by dynamically choosing the degree of scan parallelism.
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Indexallokation in Parallelen DatenbanksystemenStöhr, Thomas 23 October 2018 (has links)
Die effiziente Nutzung von Zugriffsstrukturen ist eine wichtige Voraussetzung für die performante Durchführung von Datenbankanfragen. Die in Parallelen Datenbanksystemen vom Typ Shared-Nothing übliche, durch die Allokationsstrategie für Relationen weitgehend vorgegebene Indexallokation führt oftmals zu unnötigen I/O-, Verarbeitungs- und Kommunikationskosten. Parallele Shared-Disk Datenbanksysteme bieten durch ihren gemeinsamen Plattenzugriff ein hohes Potential zur flexiblen Allokation von Indexstrukturen. Wir präsentieren eine Klassifikation und eine qualitative Bewertung von Indexallokations-Strategien für diese Architekturklasse, die zeigt, daß sich durch die flexible Wahl von Größen wie Verteilattribut und Verteilgrad die Performanz der parallelen Indexverarbeitung steigern läßt.
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Controlling Disk Contention for Parallel Query Processing in Shared Disk Database SystemsRahm, Erhard, Stöhr, Thomas 08 July 2019 (has links)
Shared Disk database systems offer a high flexibility for parallel transaction and query processing. This is because each node can process any transaction, query or subquery because it has access to the entire database. Compared to Shared Nothing, this is particularly advantageous for scan queries for which the degree of intra-query parallelism as well as the scan processors themselves can dynamically be chosen. On the other hand, there is the danger of disk contention between subqueries, in particular for index scans. We present a detailed simulation study to analyze the effectiveness of parallel scan processing in Shared Disk database systems. In particular, we investigate the relationship between the degree of declustering and the degree of scan parallelism for relation scans, clustered index scans, and non-clustered index scans. Furthermore, we study the usefulness of disk caches and prefetching for limiting disk contention. Finally, we show the importance of dynamically choosing the degree of scan parallelism to control disk contention in multi-user mode.
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High-performant, Replicated, Queue-oriented Transaction Processing Systems on Modern Computing InfrastructuresThamir Qadah (11132985) 27 July 2021 (has links)
With the shifting landscape of computing hardware architectures and the emergence of new computing environments (e.g., large main-memory systems, hundreds of CPUs, distributed and virtualized cloud-based resources), state-of-the-art designs of transaction processing systems that rely on conventional wisdom suffer from lost performance optimization opportunities. This dissertation challenges conventional wisdom to rethink the design and implementation of transaction processing systems for modern computing environments.<div><br></div><div>We start by tackling the vertical hardware scaling challenge, and propose a deterministic approach to transaction processing on emerging multi-sockets, many-core, shared memory architecture to harness its unprecedented available parallelism. Our proposed priority-based queue-oriented transaction processing architecture eliminates the transaction contention footprint and uses speculative execution to improve the throughput of centralized deterministic transaction processing systems. We build QueCC and demonstrate up to two orders of magnitude better performance over the state-of-the-art.<br></div><div><br></div><div>We further tackle the horizontal scaling challenge and propose a distributed queue-oriented transaction processing engine that relies on queue-oriented communication to eliminate the traditional overhead of commitment protocols for multi-partition transactions. We build Q-Store, and demonstrate up to 22x improvement in system throughput over the state-of-the-art deterministic transaction processing systems.<br></div><div><br></div><div>Finally, we propose a generalized framework for designing distributed and replicated deterministic transaction processing systems. We introduce the concept of speculative replication to hide the latency overhead of replication. We prototype the speculative replication protocol in QR-Store and perform an extensive experimental evaluation using standard benchmarks. We show that QR-Store can achieve a throughput of 1.9 million replicated transactions per second in under 200 milliseconds and a replication overhead of 8%-25%compared to non-replicated configurations.<br></div>
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