1 / 27

Towards Robust Indexing for Ranked Queries

Towards Robust Indexing for Ranked Queries. Dong Xin, Chen Chen, Jiawei Han Department of Computer Science University of Illinois at Urbana-Champaign VLDB 2006. Outline . Introduction Robust Index Compute Robust Index Exact Solution Approximate Solution Multiple Indices

amelie
Download Presentation

Towards Robust Indexing for Ranked Queries

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Towards Robust Indexing for Ranked Queries Dong Xin, Chen Chen, Jiawei Han Department of Computer Science University of Illinois at Urbana-Champaign VLDB 2006

  2. Outline • Introduction • Robust Index • Compute Robust Index • Exact Solution • Approximate Solution • Multiple Indices • Performance Study • Discussion and Conclusions

  3. Introduction Sample Database R Ranked Query Select top 3 * from R order by A1+A2 asc Linear Ranking Functions Query Results

  4. Efficient Processing of Ranked Queries • Naïve Solution: scan the whole database and evaluate all tuples • Using indices or materialized views • Distributed Indexing • Sort each attribute individually and merge attributes by a threshold algorithm (TA) [Fagin et al, PODS’96,’99,’01] • Spatial Indexing • Organize tuples into R-tree and determine a threshold to prune the search space [Goldstain et al, PODS’97] • Organize tuples into R-tree and retrieve data progressively [Papadias et al, SIGMOD’03] • Sequential Indexing • Organize tuples into convex hulls [Chang et al, SIGMOD’00] • Materialize ranked views according to the preference functions [Hristidis et al, SIGMOD’01] • And More…

  5. Sequential Indexing • Sequential Index (ranked view) • Linearly sort tuples • No sophisticated data structures • Sequential data access (good for database I/O) • Representative work • Onion [Chang et al, SIGMOD’00] • PREFER [Hristidis et al, SIGMOD’01] • Our proposal: Robust Index

  6. Review: Onion Technique Sample Database R A1 Index by Convex hull Retrieve data layer by layer until the top-k results are found In worst case, retrieve top-k layers of tuples t1 Second layer t2 t6 t3 t7 t8 t4 t5 First layer A2 If a and b are non-negative (a, b are weighing parameters in linear ranking function) Index by Convex Shell Expect less number of tuples in each layer A1 t1 Second layer Ranked Query t2 t6 Select top 3 * from R order by aA1+bA2 asc t3 t7 t8 t4 t5 First layer A2

  7. Review: PREFER System Sample Database R Index by the ranking function: A1+A2 Index on preference ranking function A1 t1 Given query ranking function: A1+2A2 t2 t6 t3 t7 t8 Map query ranking function to index ranking function Will retrieve t1, t2, t3, t4, t6, t7 t4 t5 A2 Ranked Query Select top 3 * from R order by w1A1+w2A2 asc Query ranking function Map from query to preference

  8. Comments on Sequential Indexing • PREFER • Works extremely well when query functions are close to the index function; Sensitive to query weights • Onion • Less sensitive to query weights; Can we do better? • Both methods • Require considerable online computation • Motivation for robust indexing • Not sensitive to query weights • Push most computation to index building phase Average #tuples retrieved for 10 random queries asking for top-50 answers Query weights are randomly selected from 1,2,3,4

  9. Outline • Introduction • Robust Index • Compute Robust Index • Exact Solution • Approximate Solution • Multiple Indices • Performance Study • Discussion and Conclusions

  10. Robust Indexing: Motivating Example A1 Index by Convex hull (shell) Organize data layer by layer In order to keep the convexity, each layer is built conservatively t1 Second layer t2 t6 t3 t7 t8 t4 t5 First layer Robust Index Organize data layer by layer Exploit dominating properties between data and push a tuple as deep as possible A2 A1 Layer 4 t1 Layer 3 t2 Layer 3 t6 t3 t7 t8 t7: dominated by t2 and t4 (for any query, at least one of t2 and t4 ranks before t7) t4 t5 First layer t7: dominated by t3 and t5 A2

  11. Robust Indexing: Formal Definition • How does it work? • Offline phase • Put each tuple in its deepest layer: the minimal (best) rank of all possible linear queries • Online phase • Retrieve tuples in top-k layers • Evaluate all of them, and report top-k • What are expected? • Correctness • Less tuples in each layer than convex hull • If a tuple does not belong to top-k for any query, it will not be retrieved

  12. Robust Indexing: Appealing Properties • Database Friendly • No online algorithm required • Simply use the following SQL statement Select top k * from R where layer <=k order by Frank • Space efficient • Suppose the upper bound of the value k is given (e.g. k<=100) • Only need to index those tuples in top 100 layers • Robust indexing uses the minimal space comparing with other alternatives

  13. Outline • Introduction • Robust Index • Compute Robust Index • Exact Solution • Approximate Solution • Multiple Indices • Performance Study • Discussion and Conclusions

  14. Robust Indexing: Algorithm Highlights • Exact Solution • Compute the deepest layer for each tuple • Complexity: • n: number of tuples • d: number of dimensions • Approximate Solution • Compute the lower bound layer for each tuple • Complexity: • Multiple Indices • Transform R to different subspaces by linear transformation • Build an index in each subspace

  15. Exact Solution Task: to compute the minimal rank over all possible linear queries for tuple t L1 A1 L2 t1 Given a query Q, with ranking function F=w1A1+w2A2, 0<=w1,w2<=1, and w1+w2=1 L3 t6 t2 L4 t Q is one-to-one mapped to a line L e.g. A1+2A2 maps to L1 t5 t3 t4 Alternative Solution: Only enumerate (w1,w2) whose corresponding line passes t and another tuple, e.g., L1, … ,L4 Do not consider t3 and t6 because the corresponding weights does not satisfy 0<=w1,w2<=1 A2 Naïve Proposal: Enumerate all possible combinations of (w1,w2) Not feasible since the enumerating space is infinite

  16. Exact Solution, cont. Task: to compute the minimal rank over all possible linear queries for tuple t L1 LV A1 L2 t1 Given a query Q, with ranking function F=w1A1+w2A2, 0<=w1,w2<=1, and w1+w2=1 L3 t6 t2 L4 LH t t5 Lv=>L1: minimal rank is 4 (after t1, t2, t3) t3 t4 L1=>L2: minimal rank is 3 (after t2, t3) A2 L2=>L3: minimal rank is 4 (after t2, t3, t4) Complexity: to sort all lines takes O(n log n), to compute minimal rank for all t, In general, L3=>L4: minimal rank is 3 (after t3, t4) L4=>LH: minimal rank is 4 (after t3, t4, t5) Minimal rank (the deepest layer) of t is 3

  17. Approximate Solution Task: to compute the lower bould of the minimal rank of tuple t I I4 A1 IV I3 I2 Four regions II: dominating region, data ranked before t IV: dominated region, data ranked after t I and III? I1 t III4 III3 II III III2 III1 A2 Step 1: Partition regions I and III Lower Bounding Theorem [Minimal ranking of t] >= card(II) + min( card(I3+I2+I1), card(I2+I1+III1), card(I1+III1+III2), card(III1+III2+III3)) Step 2: Count cardinalities of region II and sub-regions I1,…,I4, III1,…,III4 Step 3: Match the cardinalities of the sub-regions and compute the lower bound

  18. Approximate Solution, Cont. Step 2: Count cardinalities of region II and sub-regions I1,…,I4, III1,…,III4 I I4 A1 IV I3 L I2 Count the cardinality of region II? 1. All tuples in region II dominate t 2. A reversed version of skyline problem 3. Standard divide and conquer solution (details in the paper) I1 t III4 III3 II III III2 III1 A2 Count the cardinality of region I1? Suppose t: (a1,a2) Line L: A1 + 0.25A2=a1 + 0.25a2 Tuples in region I1 satisfy -A1 <= -a1 A1+0.25A2 <= a1 + 0.25 a2 A1=-A1 A2=A1+0.25A2

  19. Quality of the Approximate Solution • Complexity: • B: number of partitions in each subspace • n: number of tuples • d: number of dimensions • Approximate quality: • Assume data forms a uniform distribution • Each subspace is partitioned evenly • Partitioning according to the data distribution is an important and interesting future topic

  20. Multiple Indices • Why? • To relax the constraint • To decompose and strengthen the constraints • How? (e.g., for w1<=w2) • Linearly transform R to R’, and build index on R’ (A1,A2) => (A1+A2, A2) • Rewrite query weights (w1,w2) => (w1,w2-w1) Ranking function: F=w1A1+w2A2 Relax Ranking function: F=w1A1+w2A2 Where 0<=w1,w2<=1 Strengthen Ranking function: F=w1A1+w2A2 Where 0<=w1<=w2<=1, or 0<=w2<=w1<=1 Data are projected to a smaller subspace (e.g., A1’ >=A2’ in the transformed subspace) Tuples can be pushed deeper since more domination can be found

  21. Multiple Indices, Cont. Number of tuples in top-k layers Using the same index space, robust indexing can build 8 indices (if the value of k is up bounded by 100) Synthetic Data: 10K tuples

  22. Outline • Introduction • Robust Index • Compute Robust Index • Exact Solution • Approximate Solution • Multiple Indices • Performance Study • Discussion and Conclusions

  23. Performance Study • Data • Synthetic data • Real dataset (abalone3D, cover3D) • Measure • Number of tuples retrieved • Execution time not reported, but the robust indexing is expected to be even better • Approaches for comparison • Onion (convex shell) • PREFER • Approximate Robust Indexing (AppRI), #partition=10

  24. Index Construction Time Convex Shell, Convex Hull and AppRI are implemented by C++ Construction time on PREFER is not included since it is implemented in Java Using the system default parameter, PREFER takes more than 1200 seconds on the 50k data set

  25. Query Performance Average Number of tuples retrieved on synthetic data Average Number of tuples retrieved on Cover3D data set

  26. Multiple Indices (Views) Synthetic Data, 3 dimensions Build 3 robust indices by decompose the weighting parameters: w1=max(w1,w2,w3) w2=max(w1,w2,w3) w2=max(w1,w2,w3)

  27. Discussion and Conclusions • Strength • Easy to integrate with current DBMS • Good query performance • Practical construction complexity • Limitation • Online index maintenance is expensive (some weaker maintaining strategies available) • Indexing high dimensional data remains a challenging problem

More Related