[go: up one dir, main page]
More Web Proxy on the site http://driver.im/ skip to main content
10.1145/1807167.1807206acmconferencesArticle/Chapter ViewAbstractPublication PagesmodConference Proceedingsconference-collections
research-article

FAST: fast architecture sensitive tree search on modern CPUs and GPUs

Published: 06 June 2010 Publication History

Abstract

In-memory tree structured index search is a fundamental database operation. Modern processors provide tremendous computing power by integrating multiple cores, each with wide vector units. There has been much work to exploit modern processor architectures for database primitives like scan, sort, join and aggregation. However, unlike other primitives, tree search presents significant challenges due to irregular and unpredictable data accesses in tree traversal.
In this paper, we present FAST, an extremely fast architecture sensitive layout of the index tree. FAST is a binary tree logically organized to optimize for architecture features like page size, cache line size, and SIMD width of the underlying hardware. FAST eliminates impact of memory latency, and exploits thread-level and datalevel parallelism on both CPUs and GPUs to achieve 50 million (CPU) and 85 million (GPU) queries per second, 5X (CPU) and 1.7X (GPU) faster than the best previously reported performance on the same architectures. FAST supports efficient bulk updates by rebuilding index trees in less than 0.1 seconds for datasets as large as 64Mkeys and naturally integrates compression techniques, overcoming the memory bandwidth bottleneck and achieving a 6X performance improvement over uncompressed index search for large keys on CPUs.

References

[1]
D. Abadi, S. Madden, and M. Ferreira. Integrating compression and execution in column-oriented database systems. In SIGMOD, pages 671--682, 2006.
[2]
D. A. Alcantara, A. Sharf, F. Abbasinejad, S. Sengupta, et al. Real-time parallel hashing on the GPU. ACM Transactions on Graphics, 28(5), Dec. 2009.
[3]
V. H. Allan, R. B. Jones, R. M. Lee, and S. J. Allan. Software pipelining. ACM Comput. Surv., 27(3):367--432, 1995.
[4]
L. Arge. The buffer tree: A technique for designing batched external data structures. Algorithmica, 37(1):1--24, 2003.
[5]
R. Bayer and K. Unterauer. Prefix b-trees. ACM Trans. Database Syst., 2(1):11--26, 1977.
[6]
D. Belazzougui, P. Boldi, R. Pagh, and S. Vigna. Theory and practise of monotone minimal perfect hashing. In ALENEX, pages 132--144, 2009.
[7]
C. Binnig, S. Hildenbrand, and F. Färber. Dictionary-based order-preserving string compression for column stores. In SIGMOD, pages 283--296, 2009.
[8]
P. Bohannon, P. Mcllroy, and R. Rastogi. Main-memory index structures with fixed-size partial keys. In SIGMOD, pages 163--174, 2001.
[9]
S. Chen, P. B. Gibbons, and T. C. Mowry. Improving index performance through prefetching. SIGMOD Record, 30(2):235--246, 2001.
[10]
S. Chen, P. B. Gibbons, T. C. Mowry, et al. Fractal prefetching b+-trees: optimizing both cache and disk performance. In SIGMOD, pages 157--168, '02.
[11]
J. Chhugani, A. D. Nguyen, V.W. Lee,W. Macy, et al. Efficient implementation of sorting on multi-core SIMD CPU architecture. PVLDB, 1(2), 2008.
[12]
J. Cieslewicz and K. A. Ross. Adaptive aggregation on chip multiprocessors. In VLDB, pages 339--350, 2007.
[13]
D. Comer. Ubiquitous b-tree. ACM Comput. Surv., 11(2):121--137, 1979.
[14]
E. A. Fox, Q. F. Chen, A. M. Daoud, and L. S. Heath. Order-preserving minimal perfect hash functions. ACM Trans. Inf. Syst., 9(3):281--308, 1991.
[15]
J. Goldstein, R. Ramakrishnan, and U. Shaft. Compressing relations and indexes. In ICDE, pages 370--379, 1998.
[16]
G. Graefe and P.-A. Larson. B-tree indexes and cpu caches. In ICDE, pages 349--358, 2001.
[17]
G. Graefe and L. Shapiro. Data compression and database performance. In Applied Computing, pages 22--27, Apr 1991.
[18]
R. A. Hankins and J. M. Patel. Effect of node size on the performance of cache-conscious b+-trees. In SIGMETRICS, pages 283--294, 2003.
[19]
A. L. Holloway, V. Raman, G. Swart, and D. J. DeWitt. How to barter bits for chronons: tradeoffs for database scans. In SIGMOD, pages 389--400, 2007.
[20]
B. R. Iyer and D. Wilhite. Data compression support in databases. In VLDB, pages 695--704, 1994.
[21]
T. Kaldewey, J. Hagen, A. D. Blas, and E. Sedlar. Parallel search on video cards. In USENIX Workshop on Hot Topics in Parallelism, 2009.
[22]
C. Kim, E. Sedlar, J. Chhugani, T. Kaldewey, et al. Sort vs. hash revisited: Fast join implementation on multi-core CPUs. PVLDB, 2(2):1378--1389, 2009.
[23]
T. J. Lehman and M. J. Carey. A study of index structures for main memory database management systems. In VLDB, pages 294--303, 1986.
[24]
NVIDIA. NVIDIA CUDA Programming Guide 2.3. 2009.
[25]
J. Rao and K. A. Ross. Cache conscious indexing for decision support in main memory. In VLDB, pages 78--89, 1999.
[26]
J. Rao and K. A. Ross. Making b+- trees cache conscious in main memory. In SIGMOD, pages 475--486, 2000.
[27]
M. Reilly. When multicore isn't enough: Trends and the future for multi-multicore systems. In HPEC, 2008.
[28]
B. Schlegel, R. Gemulla, and W. Lehner. k-ary search on modern processors. In DaMoN, pages 52--60, 2009.
[29]
L. Seiler, D. Carmean, E. Sprangle, T. Forsyth, et al. Larrabee: A Many-Core x86 Architecture for Visual Computing. SIGGRAPH, 27(3), 2008.
[30]
T. Willhalm, N. Popovici, Y. Boshmaf, H. Plattner, et al. Simd-scan: Ultra fast in-memory scan using vector processing units. PVLDB, 2(1):385--394, 2009.
[31]
J. Zhou and K. A. Ross. Implementing database operations using simd instructions. In SIGMOD Conference, pages 145--156, 2002.
[32]
J. Zhou and K. A. Ross. Buffering accesses to memory resident index structures. In VLDB, pages 405--416, 2003.
[33]
M. Zukowski, S. Heman, N. Nes, and P. Boncz. Super-scalar ram-cpu cache compression. In ICDE, page 59, 2006

Cited By

View all
  • (2024)ClickHouse - Lightning Fast Analytics for EveryoneProceedings of the VLDB Endowment10.14778/3685800.368580217:12(3731-3744)Online publication date: 1-Aug-2024
  • (2024)Revisiting B-tree Compression: An Experimental StudyProceedings of the ACM on Management of Data10.1145/36549722:3(1-25)Online publication date: 30-May-2024
  • (2024)Hyper: A High-Performance and Memory-Efficient Learned Index via Hybrid ConstructionProceedings of the ACM on Management of Data10.1145/36549482:3(1-26)Online publication date: 30-May-2024
  • Show More Cited By

Index Terms

  1. FAST: fast architecture sensitive tree search on modern CPUs and GPUs

    Recommendations

    Comments

    Please enable JavaScript to view thecomments powered by Disqus.

    Information & Contributors

    Information

    Published In

    cover image ACM Conferences
    SIGMOD '10: Proceedings of the 2010 ACM SIGMOD International Conference on Management of data
    June 2010
    1286 pages
    ISBN:9781450300322
    DOI:10.1145/1807167
    Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

    Sponsors

    Publisher

    Association for Computing Machinery

    New York, NY, United States

    Publication History

    Published: 06 June 2010

    Permissions

    Request permissions for this article.

    Check for updates

    Author Tags

    1. compression
    2. cpu
    3. data-level parallelism
    4. gpu
    5. thread-level parallelism
    6. tree search

    Qualifiers

    • Research-article

    Conference

    SIGMOD/PODS '10
    Sponsor:
    SIGMOD/PODS '10: International Conference on Management of Data
    June 6 - 10, 2010
    Indiana, Indianapolis, USA

    Acceptance Rates

    Overall Acceptance Rate 785 of 4,003 submissions, 20%

    Contributors

    Other Metrics

    Bibliometrics & Citations

    Bibliometrics

    Article Metrics

    • Downloads (Last 12 months)159
    • Downloads (Last 6 weeks)11
    Reflects downloads up to 12 Dec 2024

    Other Metrics

    Citations

    Cited By

    View all
    • (2024)ClickHouse - Lightning Fast Analytics for EveryoneProceedings of the VLDB Endowment10.14778/3685800.368580217:12(3731-3744)Online publication date: 1-Aug-2024
    • (2024)Revisiting B-tree Compression: An Experimental StudyProceedings of the ACM on Management of Data10.1145/36549722:3(1-25)Online publication date: 30-May-2024
    • (2024)Hyper: A High-Performance and Memory-Efficient Learned Index via Hybrid ConstructionProceedings of the ACM on Management of Data10.1145/36549482:3(1-26)Online publication date: 30-May-2024
    • (2024)CPMA: An Efficient Batch-Parallel Compressed Set Without PointersProceedings of the 29th ACM SIGPLAN Annual Symposium on Principles and Practice of Parallel Programming10.1145/3627535.3638492(348-363)Online publication date: 2-Mar-2024
    • (2024)A Fast Learned Key-Value Store for Concurrent and Distributed SystemsIEEE Transactions on Knowledge and Data Engineering10.1109/TKDE.2023.3327009(1-14)Online publication date: 2024
    • (2024)Learned index for non-key queriesKnowledge and Information Systems10.1007/s10115-024-02233-0Online publication date: 25-Sep-2024
    • (2024)MM-DIRECTThe VLDB Journal10.1007/s00778-024-00846-z33:3(859-882)Online publication date: 27-Mar-2024
    • (2024)Introduction to the Artificial Intelligence Balancing ProblemThe Balancing Problem in the Governance of Artificial Intelligence10.1007/978-981-97-9251-1_1(1-16)Online publication date: 13-Nov-2024
    • (2023)ESL: A High-Performance Skiplist with Express LaneApplied Sciences10.3390/app1317992513:17(9925)Online publication date: 1-Sep-2023
    • (2023)RTIndeX: Exploiting Hardware-Accelerated GPU Raytracing for Database IndexingProceedings of the VLDB Endowment10.14778/3625054.362506316:13(4268-4281)Online publication date: 1-Sep-2023
    • Show More Cited By

    View Options

    Login options

    View options

    PDF

    View or Download as a PDF file.

    PDF

    eReader

    View online with eReader.

    eReader

    Media

    Figures

    Other

    Tables

    Share

    Share

    Share this Publication link

    Share on social media