13. External Sorting

13. External Sorting • Motivation • 2-way External Sort: Memory, passes,cost • General External Sort: Memory, passes, cost • Optimizations • Snowplow • Double Buffering • Forecasting • Using a B+ tree index • Bucket Sort • Intergalactic Standard Reference • Graefe, Implementing Sorting in Database Systems • http://portal.acm.org/citation.cfm?id=1132964

Learning Objectives • Derive formula for cost of external merge sort • Derive amount of memory needed to sort a file in 2 passes, using merge or bucket sort • Describe algorithm for generating longer initial runs and identify its best and worst cases • Describe forecasting and why it is useful • Identify when indexes should be used for sorting • Identify the pros and cons of external bucket vs merge sort.

Why sort? • A classic problem in computer science! • Exercises many software and hardware features • Data is often requested in sorted order • e.g., find students in increasing gpa order • Sorting is first step in bulk loading B+ tree index. • Sorting useful for some query processing algoritms (Chapter 14) • Problem: sort 1Gb of data with 1Mb of RAM. • why not virtual memory?

Sort algorithms? • If the data can fit in memory, which sort algorithm is best? • But most DBMS files will not fit in available memory • If the data is larger than memory, try the same alg. • Suppose • for this data, your sort alg. requires 220 random memory accesses • Memory access takes 1 microsec, disk takes 10 millisecs. • How much time is required to do your sort algorithm’s memory accesses? • If there is enough memory to hold the data? • If the data is four times the size of memory?

External Sorts • Definition: When data is larger than memory. • An aside: What is “Memory”? • Physical memory? The DBMS is not the only player • We concluded that most in-memory sort algs won’t be effective for external sorting. • What sort algorithms are best for external sort? • Sort-based • Hash-based

13. Sorting 2-Way External Merge Sort: Memory? • Pass 0: Read a page, sort it, write it. • How many buffer pages needed? • Pass 1, 2, 3, …, etc.: • How many buffer pages needed? INPUT 1 OUTPUT INPUT 2 Main memory buffers Result of Pass k+1 Result of Pass k

2-Way External Merge Sort: Passes? • Assume file is N pages • Run = sorted subfile • What happens in pass Zero? • How many runs are produced? • What is the cost in I/Os? • What happens in pass 1? • What happens in pass i? • How many passes are required? • What is the total cost?

13. Sorting Two-Way External Merge Sort: Cost 6,2 2 Input file 3,4 9,4 8,7 5,6 3,1 PASS 0 1,3 2 1-page runs 3,4 2,6 4,9 7,8 5,6 • Each pass we read + write each page in file. • N pages in the file => the number of passes • So total cost is: • Idea:Divide and conquer: sort subfiles and merge PASS 1 4,7 1,3 2,3 2-page runs 8,9 5,6 2 4,6 PASS 2 2,3 4,4 1,2 4-page runs 6,7 3,5 6 8,9 I/Os PASS 3 1,2 2,3 3,4 8-page runs 4,5 6,6 7,8 9

13. Sorting INPUT 1 . . . . . . INPUT 2 . . . OUTPUT INPUT B-1 Disk Disk B Main memory buffers General External Merge Sort • Suppose we have more than 3 buffer pages. • To sort a file with N pages using B buffer pages: • Pass 0: use B buffer pages. How many sorted runs of B pages each are produced? Cost? • Pass 1,2, …, etc.: merge B-1 runs. • How many runs are created after pass i? Cost of pass i? • How many passes? Total Cost?

13. Sorting Cost of External Merge Sort • Number of passes: • Cost = 2N * (# of passes) • E.g., with 5 buffer pages, to sort 108 page file • Number of passes is (1 +  log4 108/5 ) = 4 • Cost is 2(108)*4 • Pass 0: Output is = 22 sorted runs of 5 pages each (last run is only 3 pages) • Pass 1: = 6 sorted runs of 20 pages each (last run is only 8 pages) • Pass 2: 2 sorted runs, 80 pages and 28 pages • Pass 3: Sorted file of 108 pages

How much memory is needed to sort a file in one or two passes? • N = number of data pages, B = memory pages available • To sort in One pass: N  B • To Sort in Two passes: 1+logB-1N/B 2 • N/B  (B-1)1 • Approximating B-1 by B, this yields • N  B • For example, if pages are 4KBytes, a 4GByte file can be sorted in Two Passes with ? buffers.

Sorting in 2 passes: graphical proof Each run, 1xB pages • File is B pages wide • Each run is B pages • File is x pages high • Merge x runs in pass 1 • xB since we must merge x runs in B pages of memory • So N=xB BB or  NB The File, N pages x B

Memory required for 2-pass sort Assuming page size of 4K

Can we always sort in 1 or 2 passes? • Assume only one query is active, and there is at least 1 gig of physical RAM. • Yes: DB2,Oracle, SQLServer, MySQL • They allocate all available memory to queries • Tricky to manage memory allocation as queries need more memory during execution • No: Postgres • Memory allocated to each query, for sort and other purposes, is fixed by a config parameter. • Sort memory is typically a few meg, in case there may be many queries executing.

Extremes of Sorting One Pass: N =B, 1-pass sort, cost = N N B N Original Data Sorted Data Quick-sort Two Pass: N = B2, 2-pass sort, cost = 3N B B N B 12..B B Sorted Data Original Data B Runs Merge Quicksort into B runs, length B

Extreme Problems • Most sorting of large data falls between these two extremes • If we apply the intergalactic standard sort-merge algorithm, in every textbook, the cost for any dataset with B<N<B2 will be 3M. • Must we always pay that large price? • Might there be an algorithm that is a hybrid of the two extremes?

Hybrid Sort when N  3B • The key idea of hybrid sort is don’t waste memory. • Here is an example of the hybrid sort algorithm when N is approximately 3B. One+ Pass: M  3B, 2-pass sort, cost = 3M – 2B B B N Sorted Data B B Original Data Runs Merge the runs on disk with the run in memory Quicksort into runs, length B, leaving the last run in memory

B B N Sorted Data 12..K B B 12..K Original Data -1 Merge the runs on disk with the run in memory Quicksort into runs, length B, leaving the last run in memory Runs B-k pages Hybrid Sort in general • Let k = N/B • Arrange R so the last run is B-k pages • Cost is N + 2(N – (B-k)) = 3N -2B + 2(N/B) = 3N – 2( B-N/B) • When N=B, cost is N+1. When N=B2, cost is 3N

13.3.1 Maximizing initial runs • Defn: making initial runs as long as possible. • Why is it helpful to maximize initial runs? • If initial run size is doubled, what is the time savings? • How can you maximize initial runs? • What algorithm is best?

13. Sorting Replacement Selection • Initialize empty priority queues CUR, NEXT • Read B buffer pages of data into CUR • Do • Pop record s with smallest key from CUR to current run • // key of s is now highest key in current run • If key of next input r >= key of s • //Can put in current run • insert r into CUR • else • insert r into NEXT • If CUR is empty • interchange NEXT and CUR and start a new run • Until (input is empty)

13. Sorting 2B More on Replacement Selection • Cf. Knuth, vol 3 [442], page 255. • Theorem: average length of a run in replacement sort is 2B • Worst-Case: • What is min length of a run? • How does this arise? • Best-Case: • What is max length of a run? • How does this arise? • Quicksort is faster, but ...

13. Sorting B How can we prove the Theorem? • Begin with some modeling assumptions • Data to be sorted are real numbers between 0 and 1 • Data appear at a uniform rate and distribution • A snowplow picks up one datum as one falls • Picking up a datum == pop( ) off the queue • Each datum is infinitesimal • Each run begins when the plow passes zero

13. Sorting B B 0 1 B B B 0 0 0 0 1 1 1 1 CURNEXT B 0 1 2B 2B

Snowplow: Conclusion • The figures on the previous page show that • At any time after run 0, the amount of snow = size of memory = B. • After the first run, the volume of snow removed in one circuit is 2B. • Cf. Larson and Graefe [471] • In spite of memory management problems, the snowplow optimization is very effective.

13. Sorting 13.4 I/O for External Merge Sort • What else can we do to improve performance? • We have assumed I/O is done a page at a time • Text suggests reading a blockof pages sequentially. • Pass 0: No problem • Pass 1,2,…: lowers fanin • Sometimes a win

INPUT 1 . . . . . . INPUT 2 . . . OUTPUT INPUT B-1 Disk Disk B Main memory buffers External Sort’s jerky behavior • Recall that each input is one page • What happens after the last record on a page is output?

13. Sorting Double Buffering • To reduce wait time for I/O request to complete, can prefetch into `shadow block’. • This could increase the number of passes • In practice, most files still sorted in 1-2 passes. INPUT 1 INPUT 1' INPUT 2 OUTPUT INPUT 2' OUTPUT' b block size Disk INPUT k Disk INPUT k' B main memory buffers, k-way merge

Forecasting A B C 3 5 14 34 1 33 45 55 4 6 7 9 • Cf. Knuth, vol 3, pg 324-7 • Double Buffering requires Doubling memory • What a huge waste! • Most shadow buffers lie idle, unused, wasted. • How can we forecast which shadow buffers will be needed first? • Forecasting can achieve performance of double buffering with little memory 88 91 93 99 50 65 74 83 56 57 58 59

13. Sorting Sorting Records! • Sorting has become a blood sport! • Parallel sorting is the name of the game ... • www.research.microsoft.com/barc/SortBenchmark

13. Sorting Using B+ Trees for Sorting • Scenario: Table to be sorted has B+ tree index on sorting column(s). • Idea: Can retrieve records in order by traversing leaf pages. • Is this a good idea? • Cases to consider: • B+ tree is clusteredGood idea! • B+ tree is not clusteredCould be a very bad idea!

Clustered B+ Tree Used for Sorting • Cost: root to the left-most leaf, then retrieve all leaf pages (Alternative 1) • If Alternative 2 is used? Additional cost of retrieving data records: each page fetched just once. Index (Directs search) Data Entries ("Sequence set") Data Records • Always better than external sorting!

Unclustered B+ Tree Used for Sorting • Alternative (2) for data entries; each data entry contains rid of a data record. In general, one I/O per data record! Index (Directs search) Data Entries ("Sequence set") Data Records

OUTPUT 1 Disk Bucket Sort • Suppose search key values are 0-K • B pages in memory, N pages in the file • Pass 0: Partition the file into B-1 intervals • Inervals are not runs! • If the interval fits in one page, sort it [0,K/(B-1)) . . . [K/(B-1),2K/(B-1)) OUTPUT 2 INPUT . . . OUTPUT B-1 [(B-2)K/(B-1),K) B Main memory buffers Disk

Bucket sort cost • What happens after pass 0 • ? intervals, each ? long • After pass 1? • ? intervals, each ? long • How much memory is required to sort in two passes? • Each interval is at most one page, or ? • Same as for external merge sort

External Merge Sort vs External Bucket Sort • Approximately the same I/O cost • Same memory requirement for two passes • Same number of passes required to sort • Bucket sort has less CPU cost • Bucketizing is much cheaper than sorting/merging • But bucket sort is subject to skew • Thus merge sort is used in practice

13. External Sorting

13. External Sorting

Presentation Transcript

External Sorting

External Sorting

External Sorting

External Sorting

External sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting

External Sorting